Illumination system particularly for microlithography

ABSTRACT

There is provided an illumination system for scannertype microlithography along a scanning direction with a light source emitting a wavelength ≦193 nm. The illumination system includes a plurality of raster elements. The plurality of raster elements is imaged into an image plane of the illumination system to produce a plurality of images being partially superimposed on a field in the image plane. The field defines a non-rectangular intensity profile in the scanning direction.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention concerns an illumination system for wavelengths ≦193 nm as well as a projection exposure apparatus with such an illumination system.

In order to be able to further reduce the structural widths of electronic components, particularly in the submicron range, it is necessary to reduce the wavelengths of the light utilized for microlithography. Lithography with very deep UV radiation, so called VUV (Very deep UV) lithography or with soft x-ray radiation, so-called EUV (extreme UV) lithography, is conceivable at wavelengths smaller than 193 nm, for example.

2. Description of the Prior Art

An illumination system for a lithographic device, which uses EUV radiation, has been made known from U.S. Pat. No. 5,339,346. For uniform illumination in the reticle plane and filling of the pupil, U.S. Pat. No. 5,339,346 proposes a condenser, which is constructed as a collector lens and comprises at least 4 pairs of mirror facets, which are arranged symmetrically. A plasma light source is used as the light source.

In U.S. Pat. No. 5,737,137, an illumination system with a plasma light source comprising a condenser mirror is shown, in which an illumination of a mask or a reticle to be illuminated is achieved by means of spherical mirrors.

U.S. Pat. No. 5,361,292 shows an illumination system, in which a plasma light source is provided, and the point plasma light source is imaged in an annular illuminated surface by means of a condenser, which has five aspherical mirrors arranged off-center.

From U.S. Pat. No. 5,581,605, an illumination system has been made known, in which a photon beam is split into a multiple number of secondary light sources by means of a plate with concave raster elements. In this way, a homogeneous or uniform illumination is achieved in the reticle plane. The imaging of the reticle on the wafer to be exposed is produced by means of conventional reduction optics. A gridded mirror is precisely provided with equally curved elements in the illumination beam path. The contents of the above-mentioned patents are incorporated by reference.

SUMMARY OF THE INVENTION

The invention provides an illumination system for microlithography that fulfills the requirements for advanced lithography with wavelength less or equal to 193 nm. The system illuminates a structured reticle arranged in the image plane of the illumination system, which will be imaged by a projection objective onto a light sensitive substrate. In stepper-type lithography systems the reticle is illuminated with a rectangular field, wherein a pregiven uniformity of the light intensity inside the field is required, for example better than ±5%. In scanner-type lithography systems the reticle is illuminated with a rectangular or arc-shaped field, wherein a pregiven uniformity of the scanning energy distribution inside the field is required, for example better than ±5%. The scanning energy is defined as the line integral over the light intensity in the scanning direction. The shape of the field is dependent on the type of projection objective. All reflective projection objectives typically have an arc-shaped field, which is given by a segment of an annulus. A further requirement is the illumination of the exit pupil of the illumination system, which is located at the entrance pupil of the projection objective. A nearly field-independent illumination of the exit pupil is required.

One embodiment of the present invention is an illumination system for scannertype microlithography along a scanning direction with a light source emitting a wavelength ≦193 nm. The illumination system includes a plurality of raster elements. The plurality of raster elements is imaged into an image plane of the illumination system to produce a plurality of images being partially superimposed on a field in the image plane. The field defines a non-rectangular intensity profile in the scanning direction.

Another embodiment of the present invention is an illumination system for scannertype microlithography along a scanning direction with a light source emitting a wavelength ≦193 nm. This embodiment includes a first optical component having a plurality of first raster elements and a second optical component having a plurality of second raster elements. A first member of the plurality of first raster element deflects a first member of a plurality of incoming ray bundles to a first member of the plurality of second raster elements to provide an image of the first member of the plurality of first raster elements on a field in an image plane. A second member of the plurality of first raster element deflects a second member of a plurality of incoming ray bundles to a second member of the plurality of second raster elements to provide an image of the second member of the plurality of first raster elements on the field. The image of the first member of the plurality of first raster element and the image of the second member of the plurality of first raster elements are partially superimposed, and the field defines a non-rectangular intensity profile in the scanning direction.

Another embodiment of an illumination system for microlithography with a wavelength ≦193 nm, in accordance with the present invention, includes a primary light source, a first optical component, a second optical component, an image plane, and an exit pupil. The first optical component transforms the primary light source into a plurality of secondary light sources that are imaged by the second optical component in the exit pupil. The first optical component includes a plurality of raster elements that are imaged into the image plane, producing a plurality of images being superimposed partially on a field in the image plane. The field defines a non-rectangular intensity profile in a scanning direction. The plurality of raster elements deflect a plurality of incoming ray bundles to produce a plurality of deflected ray bundles with deflection angles, and at least two of the deflection angles are different from one another.

Another embodiment of an illumination system for microlithography with a wavelength ≦193 nm includes a primary light source, a first optical component, a second optical component, an image plane, and an exit pupil. The first optical component transforms the primary light source into a plurality of secondary light sources that are imaged by the second optical component in the exit pupil. The first optical component includes a plurality of first raster elements that are imaged into the image plane, producing a plurality of images being superimposed partially on a field in the image plane. The plurality of first raster elements deflect a plurality of incoming ray bundles to produce a plurality of deflected ray bundles with first deflection angles, and least two of the first deflection angles are different from one another. The first optical component also includes a plurality of second raster elements, where one of the plurality of first raster elements corresponds to one of the plurality of second raster elements. One of the plurality of first raster elements deflects one of the plurality of incoming ray bundles to the corresponding one of the plurality of second raster elements, and the plurality of second raster elements deflects the plurality of deflected ray bundles with second deflection angles to superimpose the plurality of images partially on the field. The field defines a non-rectangular intensity profile in a scanning direction.

In another embodiment of the present invention, an illumination system for scannertype microlithography along a scanning direction with a light source emitting a wavelength ≦193 nm includes a first optical component with a first optical element having a plurality of first raster elements. The plurality of first raster elements deflect a plurality of incoming ray bundles to produce a plurality of deflected ray bundles with first deflection angles. The first optical component also has a second optical element having a plurality of second raster elements. One of the plurality of first raster elements corresponds to one of the plurality of second raster elements, and one of the plurality of first raster element deflects one of the plurality of incoming ray bundles to the corresponding one of the plurality of second raster elements. At least two of the first raster elements are arranged symmetric to an axis of symmetry, and the at least two of the first raster elements deflect the plurality of incoming ray bundles with the first deflection angles to the corresponding one of the plurality of second raster elements to fill an exit pupil of the illumination system nearly point symmetric to a center of the exit pupil.

Another embodiment of an illumination system for microlithography with a wavelength ≦193 nm, in accordance with the present invention, includes a primary light source, a first optical component, a second optical component, an image plane, and an exit pupil. The first optical component transforms the primary light source into a plurality of secondary light sources that are imaged by the second optical component in the exit pupil. The first optical component includes a first optical element having a plurality of first raster elements that are imaged into the image plane, producing a plurality of images being superimposed at least partially on a field in the image plane, where the plurality of first raster elements deflect a plurality of incoming ray bundles to produce a plurality of deflected ray bundles with first deflection angles. At least two of the first deflection angles are different from one another. The first optical component also includes a second optical element having a plurality of second raster elements, where one of the plurality of first raster elements corresponds to one of the plurality of second raster elements. One of the plurality of first raster element deflects one of the plurality of incoming ray bundles to the corresponding one of the plurality of second raster elements. At least two of the plurality of first raster elements are adjacent to one another and have two corresponding second raster elements, and at least another one of the plurality of second raster elements is arranged between the two corresponding raster elements.

An illumination system in accordance with the present invention can also be employed in a projection exposure apparatus for microlithography. Such a projection exposure apparatus includes, in addition to the illumination system, a reticle located at the image plane, a light-sensitive object on a support system, and a projection objective to image the reticle onto the light-sensitive object.

Typical light sources for wavelengths between 100 nm and 200 nm are excimer lasers, for example an ArF-Laser for 193 nm, an F₂-Laser for 157 nm, an Ar₂-Laser for 126 nm and an NeF-Laser for 109 nm. For systems in this wavelength region refractive components of SiO₂, CaF₂, BaF₂ or other crystallites are used. Since the transmission of the optical materials deteriorates with decreasing wavelength, the illumination systems are designed with a combination of refractive and reflective components. For wavelengths in the EUV wavelength region, between 10 nm and 20 nm, the projection exposure apparatus is designed as all-reflective. A typical EUV light source is a Laser-Produced-Plasma-source, a Pinch-Plasma-Source, a Wiggler-Source or an Undulator-Source.

The light of this primary light source is collected by a collector unit and directed to a first optical element, wherein the collector unit and the first optical element form a first optical component. The first optical element is organized as a plurality of first raster elements and transforms, together with the collector unit, the primary light source into a plurality of secondary light sources. Each first raster element corresponds to one secondary light source and focuses an incoming ray bundle, defined by all rays intersecting the first raster element, to the corresponding secondary light source. The secondary light sources are arranged in a pupil plane of the illumination system or nearby this plane. A field lens forming a second optical component is arranged between the pupil plane and the image plane of the illumination system to image the secondary light sources into an exit pupil of the illumination system, which corresponds to the entrance pupil of a following projection objective. The images of the secondary light sources in the exit pupil of the illumination system are therefore called tertiary light sources.

The first raster elements are imaged into the image plane, wherein their images are at least partially superimposed on a field that must be illuminated. Therefore, they are known as field raster elements or field honeycombs. If the light source is a point-like source, the secondary light sources are also point-like. In this case the imaging of each of the field raster elements can be explained visually with the principle of a “camera obscura”, with the small hole of the camera obscura at the position of each corresponding secondary light source, respectively.

To superimpose the images of the field raster elements in the image plane of the illumination system the incoming ray bundles are deflected by the field raster elements with first deflection angles, which are not equal for each of the field raster elements but at least different for two of the field raster elements. Therefore individual deflection angles for the field raster elements are designed. For each field raster element a plane of incidence is defined by the incoming and deflected centroid ray selected from the incoming ray bundle. Due to the individual deflection angles, at least two of the incidence planes are not parallel.

In advanced microlithography systems the light distribution in the entrance pupil of a projection objective must fulfill special requirements such as having an overall shape or uniformity. Since the secondary light sources are imaged into the exit pupil, their arrangement in the pupil plane of the illumination system determines the light distribution in the exit pupil. With the individual deflection angles of the field raster elements a predetermined arrangement of the secondary light sources can be achieved, independent of the directions of the incoming ray bundles. For reflective field raster elements the deflection angles are generated by the tilt angles of the field raster elements. The tilt axes and the tilt angles are determined by the directions of the incoming ray bundles and the positions of the secondary light sources, to which the reflected ray bundles are directed.

For refractive field raster element the deflection angles are generated by lenslets, which have a prismatic optical power. The refractive field raster elements can be lenslets with an optical power having a prismatic contribution or they can be a combination of a single prism and a lenslet. The prismatic optical power is determined by the directions of the incoming ray bundles and the positions of the corresponding secondary light sources. Given the individual deflection angles of the first raster elements, the beam path to the plate with the raster elements can be either convergent or divergent. The slope values of the field raster elements at the centers of the field raster elements has then to be similar to the slope values of a surface with negative power to reduce the convergence of the beam path, or with positive power to increase the divergence of the beam path. Finally the field raster elements deflect the incoming ray bundles to the corresponding secondary light sources having predetermined positions depending on the illumination mode of the exit pupil.

The diameter of the beam path is preferably reduced after the collector unit to arrange filters or transmission windows with a small size. This is possible by imaging the light source with the collector unit to an intermediate image. The intermediate image is arranged between the collector unit and the plate with the field raster elements. After the intermediate image of the light source, the beam path diverges. An additional mirror to condense the diverging rays is not necessary due to the field raster elements having deflecting optical power

For contamination reasons there is a free working distance between the light source and the collector unit, which results in considerable diameters for the optical components of the collector unit and also for the light beam. Therefore the collector unit has positive optical power to generate a converging ray bundle to reduce the beam diameter and the size of the plate with field raster elements. The convergence of the light rays can be reduced with the field raster elements, if the deflection angles are designed to represent a negative optical power. For the centroid rays impinging on the centers of the field raster elements, the collector unit and the plate with the field raster elements form a telescope system. The collector unit has positive optical power to converge the centroid rays towards the optical axis, wherein the field raster elements reduce the converging angles of the centroid rays. With this telescope system the track length of the illumination system can be reduced.

Preferably, the field raster elements are tilted planar mirrors or prisms with planar surfaces, which are much easier to produce and to qualify than curved surfaces. This is possible, if the collector unit is designed to image the primary light source into the pupil plane of the illumination system, which would result in one secondary light source, if the field raster elements were omitted. The plurality of secondary light sources is generated by the plurality of field raster elements, which distribute the secondary light sources in the pupil plane according to their deflection angles. The positive optical power to focus the incoming ray bundles to the secondary light sources is completely provided by the collector unit.

Therefore the optical distance between the image-side principal plane of the collector unit and the image plane of the collector unit is nearly given by the sum of the optical distance between the image-side principal plane of the collector unit and the plate with the field raster elements, and the optical distance between the plate with the field raster elements and the pupil plane of the illumination system. Due to the planar surfaces, the field raster elements do not influence the imaging of the primary light source into one secondary light source, except for the dividing of this one secondary light source into a plurality of secondary light sources due to the deflection angles. For point-like or spherical sources the collector unit has ellipsoidal mirrors or conical lenses with a first or second focus, wherein the primary light source is arranged in the first focus, and the secondary light source is arranged in the second focus of the collector unit.

Dependent on the focusing optical power of the collector unit, the field raster elements can have a positive or negative optical power. If the focusing power of the collector unit is too low and the primary light source is imaged behind the pupil plane, the field raster elements are preferably concave mirrors or lenslets comprising positive optical power to generate the secondary light sources in or nearby the pupil plane. If the focusing power of the collector unit is too strong and the primary light source is imaged in front of the pupil plane, the field raster elements are preferably convex mirrors or lenslets comprising negative optical power to generate the secondary light sources in or nearby the pupil plane.

The field raster elements are preferably arranged in a two-dimensional array on a plate without overlapping. For reflective field raster elements the plate can be a planar plate or a curved plate. To minimize the light losses between adjacent field raster elements they are arranged only with intermediate spaces between them, which are necessary for the mountings of the field raster elements. Preferably, the field raster elements are arranged in a plurality of rows having at least one field raster element and being arranged among one another. In the rows the field raster elements are put together at the smaller side of the field raster elements. At least two of these rows are displaced relative to one another in the direction of the rows. In one embodiment each row is displaced relative to the adjacent row by a fraction of a length of the field raster elements to achieve a regular distribution of the centers of the field raster elements. The fraction is dependent on the side aspect ratio and is preferably equal to the square root of the length of one field raster element. In another embodiment the rows are displaced in such a way that the field raster elements are illuminated almost completely.

Preferably, only these field raster elements are imaged into the image plane, which is completely illuminated. This can be realized with a masking unit in front of the plate with the field raster elements, or with an arrangement of the field raster elements wherein 90% of the field raster elements are completely illuminated.

It is advantageous to insert a second optical element with second raster elements in the light path after the first optical element with first raster elements, wherein one first raster element corresponds to one of the second raster elements. Therefore, the deflection angles of the first raster elements are designed to deflect the ray bundles impinging on the first raster elements to the corresponding second raster elements. The second raster elements are preferably arranged at the secondary light sources and are designed to image together with the field lens the first raster elements or field raster elements into the image plane of the illumination system, wherein the images of the field raster elements are at least partially superimposed. The second raster elements are called pupil raster elements or pupil honeycombs. To avoid damaging the second raster elements due to the high intensity at the secondary light sources, the second raster elements are preferably arranged defocused of the secondary light sources, but in a range from 0 mm to 10% of the distance between the first and second raster elements.

For extended secondary light sources the pupil raster elements preferably have a positive optical power to image the corresponding field raster elements, which are arranged optically conjugated to the image plane. The pupil raster elements are concave mirrors or lenslets with positive optical power.

The pupil raster elements deflect incoming ray bundles impinging on the pupil raster elements with second deflection angles in such a way that the images of the field raster elements in the image plane are at least partially superimposed. This is the case if a ray intersecting the field raster element and the corresponding pupil raster element in their centers intersects the image plane in the center of the illuminated field or nearby the center. Each pair of a field raster element and a corresponding pupil raster element forms a light channel.

The second deflection angles are not equal for each pupil raster element. They are preferably individually adapted to the directions of the incoming ray bundles and the requirement to superimpose the images of the field raster elements at least partially in the image plane. With the tilt axis and the tilt angle for a reflective pupil raster element or with the prismatic optical power for a refractive pupil raster element the second deflection angle can be individually adapted.

For point-like secondary light sources the pupil raster elements only have to deflect the incoming ray bundles without focusing the rays. Therefore the pupil raster elements are preferably designed as tilted planar mirrors or prisms.

If both, the field raster elements and the pupil raster elements deflect incoming ray bundles in predetermined directions, the two-dimensional arrangement of the field raster elements can be made different from the two-dimensional arrangement of the pupil raster elements. Wherein the arrangement of the field raster elements is adapted to the illuminated area on the plate with the field raster elements, the arrangement of the pupil raster elements is determined by the kind of illumination mode required in the exit pupil of the illumination system. So the images of the secondary light sources can be arranged in a circle, but also in an annulus to get an annular illumination mode or in four decentered segments to get a Quadrupol illumination mode. The aperture in the image plane of the illumination system is approximately defined by the quotient of the half diameter of the exit pupil of the illumination system and the distance between the exit pupil and the image plane of the illumination system. Typical apertures in the image plane of the illumination system are in the range of 0.02 and 0.1. By deflecting the incoming ray bundles with the field and pupil raster elements a continuous light path can be achieved. It is also possible to assign each field raster element to any of the pupil raster elements. Therefore the light channels can be mixed to minimize the deflection angles or to redistribute the intensity distribution between the plate with the field raster elements and the plate with the pupil raster elements.

Imaging errors such as distortion introduced by the field lens can be compensated for with the pupil raster elements being arranged at or nearby the secondary light sources. Therefore the distances between the pupil raster elements are preferably irregular. The distortion due to tilted field mirrors for example is compensated for by increasing the distances between the pupil raster elements in a direction perpendicular to the tilt axis of the field mirrors. Also, the pupil raster elements are arranged on curved lines to compensate for the distortion due to a field mirror, which transforms the rectangular image field to a segment of an annulus by conical reflection. By tilting the field raster elements the secondary light sources can be positioned at or nearby the distorted grid of the corresponding pupil raster elements.

For reflective field and pupil raster elements the beam path has to be folded at the plate with the field raster elements and at the plate with the pupil raster elements to avoid vignetting. Typically, the folding axes of both plates are parallel. Another requirement for the design of the illumination system is to minimize the incidence angles on the reflective field and pupil raster elements. Therefore the folding angles have to be as small as possible. This can be achieved if the extent of the plate with the field raster elements is approximately equal to the extent of the plate with the pupil raster elements in a direction perpendicular to the direction of the folding axes, or if it differs less than ±10%.

Since the secondary light sources are imaged into the exit pupil of the illumination system, their arrangement determines the illumination mode of the pupil illumination. Typically the overall shape of the illumination in the exit pupil is circular and the diameter of the illuminated region is in the order of 60%-80% of the diameter of the entrance pupil of the projection objective. The diameters of the exit pupil of the illumination system and the entrance pupil of the projection objective are in another embodiment preferably equal. In such a system the illumination mode can be changed in a wide range by inserting masking blades at the plane with the secondary light sources to get a conventional, Dipol or Quadrupol illumination of the exit pupil.

All-reflective projection objectives used in the EUV wavelength region have typically an object field being a segment of an annulus. Therefore the field in the image plane of the illumination system in which the images of the field raster elements are at least partially superimposed has preferably the same shape. The shape of the illuminated field can be generated by the optical design of the components or by masking blades that have to be added nearby the image plane or in a plane conjugated to the image plane.

The field raster elements are preferably rectangular. Rectangular field raster elements have the advantage that they can be arranged in rows being displaced against each other. Depending on the field to be illuminated they have a side aspect ratio in the range of 5:1 and 20:1. The length of the rectangular field raster elements is typically between 15 mm and 50 mm, the width is between 1 mm and 4 mm.

To illuminate an arc-shaped field in the image plane with rectangular field raster elements the field lens preferably comprises a first field mirror for transforming the rectangular images of the rectangular field raster elements to arc-shaped images. The arc length is typically in the range of 80 mm to 105 mm, the radial width in the range of 5 mm to 9 mm. The transformation of the rectangular images of the rectangular field raster elements can be done by conical reflection with the first field mirror being a grazing incidence mirror with negative optical power. In other words, the imaging of the field raster elements is distorted to get the arc-shaped images, wherein the radius of the arc is determined by the shape of the object field of the projection objective. The first field mirror is preferably arranged in front of the image plane of the illumination system, wherein there should be a free working distance. For a configuration with a reflective reticle the free working distance has to be adapted to the fact that the rays traveling from the reticle to the projection objective are not vignetted by the first field mirror.

The surface of the first field mirror is preferably an off-axis segment of a rotational symmetric reflective surface, which can be designed aspherical or spherical. The axis of symmetry of the supporting surface goes through the vertex of the surface. Therefore a segment around the vertex is called on-axis, wherein each segment of the surfaces which does not include the vertex is called off-axis. The supporting surface can be manufactured more easily due to the rotational symmetry. After producing the supporting surface the segment can be cut out with well-known techniques.

The surface of the first field mirror can also be designed as an on-axis segment of a toroidal reflective surface. Therefore the surface has to be processed locally, but has the advantage that the surrounding shape can be produced before surface treatment.

The incidence angles of the incoming rays with respect to the surface normals at the points of incidence of the incoming rays on the first field mirror are preferably greater than 70°, which results in a reflectivity of the first field mirror of more than 80%.

The field lens comprises preferably a second field mirror with positive optical power. The first and second field mirror together image the secondary light sources or the pupil plane respectively into the exit pupil of the illumination system, which is defined by the entrance pupil of the projection objective. The second field mirror is arranged between the plane with the secondary light sources and the first field mirror.

The second field mirror is preferably an off-axis segment of a rotational symmetric reflective surface, which can be designed aspherical or spherical, or an on-axis segment of a toroidal reflective surface.

The incidence angles of the incoming rays with respect to the surface normals at the points of incidence of the incoming rays on the second field mirror are preferably lower than 25°. Since the mirrors have to be coated with multilayers for the EUV wavelength region, the divergence and the incidence angles of the incoming rays are preferably as low as possible to increase the reflectivity, which should be better than 65%. With the second field mirror being arranged as a normal incidence mirror the beam path is folded and the illumination system can be made more compact.

To reduce the length of the illumination system the field lens comprises preferably a third field mirror. The third field mirror is preferably arranged between the plane with the secondary light sources and the second field mirror.

The third field mirror has preferably negative optical power and forms together with the second and first field mirror an optical telescope system having a object plane at the secondary light sources and an image plane at the exit pupil of the illumination system to image the secondary light sources into the exit pupil. The pupil plane of the telescope system is arranged at the image plane of the illumination system. Therefore the ray bundles coming from the secondary light sources are superimposed in the pupil plane of the telescope system or in the image plane of the illumination system accordingly. The first field mirror has mainly the function of forming the arc-shaped field, wherein the telescope system is mainly determined by the negative third field mirror and the positive second field mirror.

In another embodiment the third field mirror has preferably positive optical power to generate images of the secondary light sources in a plane between the third and second field mirror, forming tertiary light sources. The tertiary light sources are imaged with the second field mirror and the first field mirror into the exit pupil of the illumination system. The images of the tertiary light sources in the exit pupil of the illumination system are called in this case quaternary light sources.

Since the plane with the tertiary light sources is arranged conjugated to the exit pupil, this plane can be used to arrange masking blades to change the illumination mode or to add transmission filters. This position in the beam path has the advantage to be freely accessible.

The third field mirror is similar to the second field mirror preferably an off-axis segment of a rotational symmetric reflective surface, which can be designed aspherical or spherical, or an on-axis segment of a toroidal reflective surface.

The incidence angles of the incoming rays with respect to the surface normals at the points of incidence of the incoming rays on the third field mirror are preferably lower than 25°. With the third field mirror being arranged as a normal incidence mirror the beam path can be folded again to reduce the overall size of the illumination system.

To avoid vignetting of the beam path the first, second and third field mirrors are preferably arranged in a non-centered system. There is no axis of symmetry for the mirrors. An optical axis can be defined as a connecting line between the centers of the used areas on the field mirrors, wherein the optical axis is bent at the field mirrors depending on the tilt angles of the field mirrors.

With the tilt angles of the reflective components of the illumination system the beam paths between the components can be bent. Therefore the orientation of the beam cone emitted by the source and the orientation of the image plane system can be arranged according to the requirements of the overall system. A preferable configuration has a source emitting a beam cone in one direction and an image plane having a surface normal that is oriented almost perpendicular to this direction. In one embodiment the source emits horizontally and the image plane has a vertical surface normal. Some light sources like undulator or wiggler sources emit only in the horizontal plane. On the other hand the reticle should be arranged horizontally for gravity reasons. The beam path therefore has to be bent between the light source and the image plane about almost 90°. Since mirrors with incidence angles between 30° and 60° lead to polarization effects and therefore to light losses, the beam bending has to be done only with grazing incidence or normal incidence mirrors. For efficiency reasons the number of mirrors has to be as small as possible.

A very compact configuration of the illumination system can be designed, if the beam path from the plate with the pupil raster elements to the field lens is crossing the beam path from the collector unit to the plate with field raster elements. This is only possible, if the field raster elements and the pupil raster elements are reflective ones and are arranged on plates being tilted to achieve the crossing of the two beam paths. The crossing of the beam paths has the advantage that the beam path after the plate with the pupil raster elements has an angle in the range of 35° to 55° with respect to the beam path in front of the plate with the field raster elements. This was achieved with only two normal incidence reflections.

By definition all rays intersecting the field in the image plane have to go through the exit pupil of the illumination system. The position of the field and the position of the exit pupil are defined by the object field and the entrance pupil of the projection objective. For some projection objectives being centered systems the object field is arranged off-axis of an optical axis, wherein the entrance pupil is arranged on-axis in a finite distance to the object plane. For these projection objectives an angle between a straight line from the center of the object field to the center of the entrance pupil and the surface normal of the object plane can be defined. This angle is in the range of 3° to 10° for EUV projection objectives. Therefore the components of the illumination system have to be configured and arranged in such a way that all rays intersecting the object field of the projection objective are going through the entrance pupil of the projection objective being decentered to the object field. For projection exposure apparatus with a reflective reticle all rays intersecting the reticle needs to have incidence angles greater than 0° to avoid vignetting of the reflected rays at components of the illumination system.

In the EUV wavelength region all components are reflective components, which are arranged preferably in such a way, that all incidence angles on the components are lower than 25° or greater than 65°. Therefore polarization effects arising for incidence angles around an angle of 45° are minimized. Since grazing incidence mirrors have a reflectivity greater than 80%, they are preferable in the optical design in comparison to normal incidence mirrors with a reflectivity greater than 65%.

The illumination system is typically arranged in a mechanical box. By folding the beam path with mirrors the overall size of the box can be reduced. This box preferably does not interfere with the image plane, in which the reticle and the reticle supporting system are arranged. Therefore it is advantageous to arrange and tilt the reflective components in such a way that all components are completely arranged on one side of the reticle. This can be achieved if the field lens comprises only an even number of normal incidence mirrors.

The illumination system as described before can be used preferably in a projection exposure apparatus comprising the illumination system, a reticle arranged in the image plane of the illumination system and a projection objective to image the reticle onto a wafer arranged in the image plane of the projection objective. Both, reticle and wafer are arranged on a support unit, which allows the exchange or scan of the reticle or wafer.

The projection objective can be a catadioptric lens, as known from U.S. Pat. No. 5,402,267 for wavelengths in the range between 100 nm and 200 nm. These systems have typically a transmission reticle. For the EUV wavelength range the projection objectives are preferably all-reflective systems with four to eight mirrors as known for example from U.S. Ser. No. 09/503,640 showing a six mirror projection lens. These systems have typically a reflective reticle.

For systems with a reflective reticle the illumination beam path between the light source and the reticle and the projection beam path between the reticle and the wafer preferably interfere only nearby the reticle, where the incoming and reflected rays for adjacent object points are traveling in the same region. If there is no further crossing of the illumination and projection beam path it is possible to separate the illumination system and the projection objective except for the reticle region.

The projection objective has preferably a projection beam path between the reticle and the first imaging element that is convergent toward the optical axis of the projection objective. Especially for a projection exposure apparatus with a reflective reticle the separation of the illumination system and the projection objective is easier to achieve.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described below on the basis of drawings.

FIG. 1: Principle diagram of the beam path of a system with two raster element plates.

FIGS. 2 a, 2 b: Imaging of the field and pupil raster elements.

FIG. 3: Path of the light beam for a rectangular field raster element in combination with a pupil raster element.

FIG. 4: Beam path according to FIG. 3 with field lens introduced in the beam path.

FIG. 5: Beam path according to FIG. 3 with two field mirrors introduced in the beam path.

FIG. 6: System with field and pupil raster elements.

FIGS. 7-14: Different arrangements of field raster elements on a field raster element plate.

FIGS. 15-17: Raster of tertiary light sources in the entrance pupil of the projection objective.

FIGS. 18-20: Relationship between illuminated surfaces of field raster element plate and pupil raster element plate as well as structural length and aperture in the reticle plane.

FIGS. 21-22: Illumination system with a collector unit, field and pupil raster elements.

FIGS. 23-24: Beam path in a system with collector unit, field and pupil raster elements.

FIG. 25-26: Illumination of the reticle of a system according to FIGS. 23-24.

FIG. 27-28: Illumination of the reticle of a system according to FIGS. 23-24 without pupil raster elements.

FIG. 29: Comparison of the intensity distribution of a system according to FIGS. 23-24 with and without pupil raster element plate.

FIG. 30: Integral scanning energy in the reticle plane of a system according to FIGS. 23-24 with pupil raster element plate.

FIG. 31: Pupil illumination for an object point in the center of the illuminated field of a system according to FIGS. 23-24 with pupil raster element plate.

FIG. 32: Total energy of the tertiary light sources of a system according to FIGS. 23-24 along the Y-axis.

FIGS. 33-39: Illumination system with a laser plasma source as a light source as well as a collector unit and two mirror units, which form a tele-system.

FIGS. 40-45: Course of the light beams in a system with collector unit as well as two tele-mirrors according to FIGS. 37-39.

FIG. 46: Illumination of the reticle of an arrangement according to FIGS. 44-45.

FIG. 47: Integral scanning energy of an arrangement according to FIGS. 40-45.

FIG. 48: Pupil illumination of a system according to FIGS. 40-45.

FIGS. 48A-48C: System for a laser-plasma source with diameter ≦50 μm and without pupil raster element plate.

FIGS. 49-52: System with a laser-plasma source, a collector and a field raster element plate with planar field raster elements.

FIGS. 53-58: Beam path in a system according to FIGS. 49-52.

FIG. 59: Illumination of the reticle with an illumination arrangement according to FIGS. 52-58.

FIG. 60: Integral scanning energy in the reticle plane of a system according to FIGS. 52-58.

FIG. 61: Pupil illumination of a system according to FIGS. 52-58.

FIG. 62: Intensity distribution in the scan direction of a system according to FIGS. 52-58.

FIG. 63A: Raster element plate with individual raster elements on a curved supporting surface.

FIG. 63B: Raster element plate with tilted raster elements on a planar supporting plate.

FIG. 64: A configuration of the invention with lenslets and prisms as raster elements in schematic presentation.

FIG. 65: A schematic view of a refractive embodiment with prisms as field raster elements.

FIG. 66: A schematic view of a refractive embodiment with field raster elements having positive and prismatic optical power.

FIG. 67: A schematic view of a refractive embodiment with field raster elements having negative and prismatic optical power.

FIG. 68: A schematic view of a refractive embodiment with field raster elements having positive and prismatic optical power and prisms as pupil raster elements.

FIG. 69: A schematic view of a refractive embodiment having an intermediate image of the primary light source.

FIG. 70: A schematic view of a reflective embodiment with convex mirrors as field raster elements and planar mirrors as pupil raster elements.

FIG. 71: A schematic view of a reflective embodiment with convex mirrors as field raster elements and concave mirrors as pupil raster elements.

FIG. 72: A schematic view of the principal setup of the illumination system.

FIG. 73: An Arrangement of the field raster elements.

FIG. 74: An Arrangement of the pupil raster elements.

FIG. 75: A schematic view of a reflective embodiment with a concave pupil-imaging field mirror and a convex field-forming field mirror.

FIG. 76: A schematic view of a reflective embodiment with a field lens comprising a telescope system and a convex field-forming field mirror.

FIG. 77: A detailed view of the embodiment of FIG. 76.

FIG. 78: Intensity distribution of the embodiment of FIG. 77.

FIG. 79: Illumination of the exit pupil of the illumination system of the embodiment of FIG. 77.

FIG. 80: A schematic view of a reflective embodiment with a crossing of the beam paths.

FIG. 81: A detailed view of the embodiment of FIG. 80.

FIG. 82: A schematic view of a reflective embodiment with two pupil planes.

FIG. 83: A schematic view of a reflective embodiment with an intermediate image of the light source.

FIG. 84: A detailed view of a projection exposure apparatus.

FIG. 85: Rectangular field in the field plane.

FIG. 86A: Superposition of a plurality of images of first raster elements in the field plane providing for a rectangular intensity profile.

FIG. 86B: Rectangular intensity profile.

FIG. 87A: Superposition of a plurality of images of first raster elements in the field plane providing for a trapezoid intensity profile.

FIG. 87B: Trapezoid intensity profile.

FIG. 88: First raster element plate with twelve first raster elements.

FIG. 89: Assignment of axis symmetric first raster elements to point-symmetric second raster elements.

FIG. 90: Field in an image plane and exit pupils for different field points.

DESCRIPTION OF THE INVENTION

It shall be shown theoretically on the basis of FIGS. 1-20, how a system can be provided for any desired illumination distribution in a plane, which satisfies the requirements with reference to uniformity and telecentricity.

In FIG. 1, a principle diagram of the beam path of a system with two plates with raster elements is illustrated. The light of the primary light source 1 is collected by means of a collector lens 3 and converted into a parallel or convergent light beam. The field raster elements 5 of the first raster element plate 7 decompose the light beam and produce secondary light sources at the site of the pupil raster elements 9. At the position of the secondary light sources the pupil plane of the illumination system is arranged. The field lens 12 images these secondary sources in the exit pupil of the illumination system or the entrance pupil of the subsequent projection objective forming tertiary light sources. The field raster elements 5 are imaged by the pupil raster elements 9 and the field lens 12 into the image plane of the illumination system. In this plane the reticle 14 is arranged. Such an arrangement is characterized by an interlinked beam path of field and pupil planes from the source up to the entrance pupil of the subsequent projection objective. For this, the designation “Köhler illumination” is also often selected.

The illumination system according to FIG. 1 is considered segmentally below. If the light intensity and aperture distribution is known in the plane of the field raster elements, the system can be described independent of source type and collector unit.

The field and pupil imaging are illustrated for the central pair of field raster element 20 and pupil raster element 22 in FIGS. 2A and 2B. The field raster element 20 is imaged on the reticle 14 or the mask by means of the pupil raster element 22 and the field lens 12. The geometric extension of the field raster element 20 determines the shape of the illuminated field in the reticle plane 14. The image scale is approximately given by the ratio of the distance from pupil raster element 22 to reticle 14 and the distance from field raster element 20 to pupil raster element 22. The field raster element 20 is designed such that an image of primary light source 1, a secondary light source, is formed at the site of pupil raster element 22. If the extension of the primary light source 1 is small, for example, approximately point-like, then all light rays run through the centers of the pupil raster elements 22. In such a case, an illumination device can be produced, in which the pupil raster element is dispensed with.

As is shown in FIG. 2B, the task of field lens 12 consists of imaging the secondary light sources in the entrance pupil 26 of projection objective 24 forming tertiary light sources. With the field lens the field imaging can be influenced in such a way that it forms the arc-shaped field by control of the distortion. The imaging scale of the field raster element image is thus almost not changed.

A special geometrical form of a field raster element 20 and a pupil raster element 22 is shown in FIG. 3.

In the form of embodiment represented in FIG. 3, the shape of field raster element 20 is selected as a rectangle. Thus, the aspect ratio of the field raster element 20 corresponds approximately to the ratio of the arc length to the annular width of the required arc-shaped field in the reticle plane. The arc-shaped field is formed by the field lens 32, as shown in FIG. 4. Without the field lens 32, as shown in FIG. 3, a rectangular field is formed in the reticle plane.

As shown in FIG. 4, one grazing-incidence field mirror 32 is used for the shaping of arc-shaped field 30. Under the constraint that the beam reflected by the reticle should not be directed back into the illumination system, one or two field mirrors 32 are required, depending on the position of the entrance pupil of the objective.

If the principal rays run divergently into the objective that is not shown, then one field mirror 32 is sufficient, as shown in FIG. 4. In the case of principal rays entering the projection objective convergently, two field mirrors are required. The second field mirror must rotate the orientation of the ring 30. Such a configuration is shown in FIG. 5.

In the case of an illumination system in the EUV wavelength region, all components must be reflective ones.

Due to the high reflection losses at λ=10 nm-14 nm, it is advantageous that the number of reflections be kept as small as possible.

In the construction of the reflective system, the mutual vignetting of the beams must be taken into consideration. This can occur due to construction of the system in a zigzag beam path or by operating with obscurations.

The design process will be described below for the preparation of a design for an EUV illumination system with any illumination in a plane, as an example. The definitions necessary for the design process are shown in FIG. 6.

First, the beam path is calculated for the central pair of raster elements. In a first step, the size of field raster elements 5 of the field raster element plate 7 will be determined. As indicated previously, the aspect ratio (x/y) results for rectangular raster elements from the shape of the arc-shaped field in the reticle plane. The size of the field raster elements is determined by the illuminated area A of the intensity distribution of the arbitrary light source in the plane of the field raster elements and the number N of the field raster elements on the raster element plate, which in turn is given by the number of secondary light sources. The number of secondary light sources results in turn from the uniformity of the field and pupil illumination.

The raster element surface A_(FRE) of a field raster element can be expressed as follows with x_(FRE), y_(FRE):

A _(FRE) =x _(FRE) ·y _(FRE)=(x _(field) /y _(field))·y ² _(FRE)

whereby x_(field), y_(field) describe the size of the rectangle, which establishes the arc-shaped field. Further, the following is valid for the number N of field raster elements:

N=A/A _(FRE) =A/[y ² _(FRE)·(x _(field) /y _(field))].

From this, there results for the size of the individual field raster element:

y _(FRE) =√{square root over (A/[N·(x _(field) /y _(field))])}

and

x _(FRE)=(x _(field) /y _(field))·y _(FRE)

The raster element size and the size of the rectangular field in the reticle plane establish the imaging scale β_(FRE) of the field raster element imaging and thus the ratio of the distances z₁ and z₂.

β_(FRE) =x _(field) /y _(field) =z ₂ /z ₁

The pregiven structural length L for the illumination system and the imaging scale β_(FRE) of the field raster element imaging determine the absolute size of z₁ and z₂ and thus the position of the pupil raster element plate. The following is valid:

z ₁ =L/(1+β_(FRE))

z ₂ =z ₁·β_(FRE)

Then, z₁ and z₂ determine in turn the curvature of the pupil raster elements. The following is valid:

$R_{FRE} = \frac{2 \cdot z_{1} \cdot z_{2}}{z_{1} + z_{2}}$

In order to image the pupil raster elements in the entrance pupil of the projection objective and to remodel the rectangular field into an arc-shaped field, a field lens comprising one or more field mirrors, preferably of toroidal form, are introduced between the pupil raster element plate and the reticle. By introducing the field mirrors, the previously given structural length is increased, since among other things, the mirrors must maintain minimum distances in order to avoid light vignetting.

The positioning of the field raster elements depends on the intensity distribution in the plane of the field raster elements. The number N of the field raster elements is pregiven by the number of secondary light sources. The field raster elements will preferably be arranged on the field raster element plate in such a way that they cover the illuminated surfaces without mutually vignetting.

In order to position the pupil raster elements, the raster pattern of the tertiary light sources in the entrance pupil of the projection objective will be given in advance. The tertiary light sources are imaged by the field lens counter to the direction of light into the secondary light sources. The aperture stop plane of this imaging is in the reticle plane. The images of the tertiary light sources give the (x, y, z) positions of the pupil raster elements which are arranged at the positions of the secondary light sources. The tilt and rotational angles remain as degrees of freedom for producing the light path between the field and pupil raster elements.

If a pupil raster element is assigned to each field raster element in one configuration of the invention, then the light path will be produced by tilting and rotating field and pupil raster elements. Thereby the light beams, generated by the field raster elements, are deviated in such a way that the center rays of the light beams all intersect the optical axis in the reticle plane.

The assignment of field and pupil raster elements can be made freely. One possibility for arrangement would be to assign spatially adjacent field and pupil raster elements. Thereby, the deflecting angles become minimal. Another possibility consists of homogenizing the intensity distribution in the pupil plane. This is made, for example, if the intensity distribution has a non-homogenous distribution in the plane of the field raster elements. If the field and pupil raster elements have similar positions, the distribution is transferred to the pupil illumination. By intermixing the light beams the light distribution in the pupil plane can be homogenized.

Advantageously, the individual components of field raster element plate, pupil raster element plate and field mirrors of the illumination system are arranged in the beam path such that a beam path free of vignetting is possible. If such an arrangement has effects on the imaging, then the individual light channels and the field mirrors must be re-optimized.

With the design process described above, illumination systems for EUV lithography are obtained for any light distribution at the plate with the field raster elements with two normal-incidence reflections for the field and pupil raster elements and one to two normal or grazing-incidence reflections for the field lens. These systems have the following properties:

-   a. An homogeneous illumination of an arc-shaped field -   b. An homogeneous and field-independent pupil illumination -   c. The combining of the exit pupil of the illumination system and     the entrance pupil of the projection objective -   d. The adjustment of a pregiven structural length -   e. The collection of nearly all light generated by the primary light     source.

Arrangements of field raster elements and pupil raster elements will be described below for one form of embodiment of the invention with field and pupil raster element plates.

First, different arrangements of the field raster elements on the field raster element plate will be considered. The intensity distribution can be selected as desired.

The introduced examples are limited to simple geometric shapes of the light distributions, such as circle, rectangle, or the coupling of several circles or rectangles, but the present invention is not limited on these shapes.

The intensity distribution will be homogeneous within the illuminated region or have a slowly varying distribution. The aperture distribution will be independent of the position inside the light distribution.

In the case of circular illumination A of field raster element plate 100, field raster elements 102 may be arranged, for example, in columns and rows, as shown in FIG. 7. As an alternative to this, the center points of the raster elements 102 can be distributed uniformly by shifting the rows over the surface, as shown in FIG. 8. The rows are displaced relatively to an adjacent row. This arrangement is better adapted to a uniform distribution of the secondary light sources in the pupil plane.

A rectangular illumination A with a arrangement of the field raster elements 102 in rows and columns is shown in FIG. 9. A displacement of the rows, as shown in FIG. 10, leads to a more uniform distribution of the secondary light sources in the pupil plane. However, without tilting the field raster elements 102 the secondary light sources are arranged within a rectangle corresponding to the arrangement of the field raster elements 102. Since the pupil raster elements are typically arranged inside a circle to get a circular illumination of the exit pupil of the illumination system, it is necessary to tilt the field and pupil raster elements to produce a continuous light path between the corresponding field and pupil raster elements.

If illumination A of field raster element plate 100 comprises several circles, A1, A2, A3, A4, for example by coupling several sources, then, intermixing is insufficient with an arrangement of the raster elements 102 with a high (x/y)-aspect ratio in rows and columns according to FIG. 11. A more uniform illumination is obtained by shifting the raster element rows, as shown in FIG. 12.

FIGS. 13 and 14 show the distribution of field raster elements 102 in the case of combined illumination from the individual rectangles A1, A2, A3, A4.

Now, for example, arrangements of the pupil raster elements on the pupil raster element plate will be described. In the arrangement of pupil raster elements, two points of view are to be considered:

-   1. For minimizing the tilt angle of field and pupil raster elements     for producing the light path, it is advantageous to maintain the     arrangement of field raster elements. This is particularly     advantageous with an approximately circular illumination of the     field raster element plate. -   2. For homogeneous filling of the pupil, the tertiary light sources,     which are images of the secondary light sources, will be distributed     uniformly in the entrance pupil of the projection objective. This     can be achieved by providing a uniform raster pattern of tertiary     light sources in the entrance pupil of the projection objective.     These are imaged counter to the direction of light with the field     lens in the plane of the pupil raster elements and determine in this     way the ideal site of the pupil raster elements, which are arranged     nearby the secondary light sources.

If the field lens is free of distortion, then the distribution of the pupil raster elements corresponds to the distribution of the tertiary light sources. However, since the field lens forms the arc-shaped field, distortion is purposely introduced. This does not involve rotational-symmetric distortion, but involves the bending of horizontal lines into arcs. In the ideal case, the y distance of the arcs remains almost constant. Real grazing-incidence field mirrors, however, also show an additional distortion in the y-direction.

A raster 110 of tertiary light sources 112 in the entrance pupil of the projection objective, which is also the exit pupil of the illumination system, is shown in FIG. 15, as it had been produced for distortion-free field lens imaging. The arrangement of the tertiary light sources 112 corresponds precisely to the pregiven arrangement of pupil raster elements.

If the field lenses are utilized for shaping the arc-shaped field, as in FIG. 2016, then the tertiary light sources 112 lie on arcs 114. If the pupil raster elements of individual rows are placed on the arcs that compensate for the distortion, then one can place the tertiary light sources again on a regular raster.

If the field lens also introduces distortion in the y-direction, then the distribution of the tertiary light sources is distorted in the y-direction, as shown in FIG. 17. This effect can be compensated by arranging the pupil raster elements on a grid that is distorted in y-direction.

The extent of the illuminated area onto the field raster element plate is determined by design of the collector unit. The extent of the illuminated area onto the pupil raster element plate is determined by the structural length of the illumination system and the aperture in the reticle plane.

As described above, the two surfaces must be fine-tuned to one another by rotating and tilting the field and pupil raster elements.

For illustration, the design of the illumination system will be explained with refractive elements. The examples, however, can be transferred directly to reflective systems. Various configurations can be distinguished for a circular illumination of field raster element plates, as presented below.

If a converging effect is introduced by tilting the field raster elements, and a diverging effect is introduced by tilting the pupil raster elements, then the beam cross section can be reduced. The tilt angles of the individual raster elements are determined by tracing the center rays for each pair of raster elements. The system acts like a telescope-system for the central rays, as shown in FIG. 18.

How far the field raster elements must be tilted, depends on the convergence of the impinging beam. If the convergence is adapted to the reduction of the beam cross section, the field raster elements can be arranged onto a planar substrate without tilting the field raster elements.

A special case results, if the convergence between the field and the pupil raster element plate corresponds to the aperture NA_(field) at the reticle, as shown in FIG. 19.

No diverging effect must be introduced by the pupil raster elements, so they can be utilized without tilting the pupil raster elements. If the light source also has a very small etendue, the pupil raster element can be completely dispensed with.

A magnification of the beam cross section is possible, if diverging effect is introduced by tilting of the field raster elements, and collecting effect is introduced by tilting the pupil raster elements. The system operates like a retro-focus system for the central rays, as shown in FIG. 20.

If the divergence of the impinging radiation corresponds to the beam divergence between field and pupil raster elements, then the field raster elements can be used without tilting the field raster elements.

Instead of the circular shape that has been described, rectangular or other shapes of illumination A of the field raster element plate are possible.

The following drawings describe one form of embodiment of the invention, in which a pinch-plasma source is used as the light source of the EUV illumination system.

The principal construction without field lens of such a form of embodiment is shown in FIG. 21; FIG. 22 shows the abbreviations necessary for the system derivation, whereby for better representation, the system was plotted linearly and mirrors were indicated as lenses. An illumination system with pinch-plasma source 200 as primary light source, as shown in FIG. 21, comprises a light source 200, a collector mirror 202, which collects the light and reflects it to the field raster element plate 204. By reflection at the field raster elements, the light is directed to the corresponding pupil raster elements of pupil raster element plate 206 and from there to reticle 208. The pinch-plasma source is an expanded light source (approximately 1 mm) with a directional radiation in a relatively small steradian region of approximately Ω=0.3 sr. Based on the etendue of the primary light source, a pupil raster element plate 206 is used.

The following specifications are used, for example, for an illumination system for EUV lithography:

-   a. Arc-shaped field: Radius R_(field)=100 mm, segment—angle 60°,     field width ±3.0 mm, which corresponds to a rectangular field of 105     mm×6 mm -   b. Aperture at the reticle: NA_(field)=0.025 -   c. Aperture at the source: NA_(source)=0.3053 -   d. Structural length L=1400.0 mm -   e. Number of field raster elements, which find place in an x-row: 4 -   f. z₁=330.0 mm

With the following equations the optical design of the illumination system can be derived with the pregiven numbers:

$\begin{matrix} {{NA}_{field} = \frac{\frac{D_{FRE}}{2}}{L}} & {\left. \Rightarrow D_{FRE} \right. = {2 \cdot L \cdot {NA}_{field}}} \\ {\frac{D_{PRE}}{x_{FRE}} = 4.0} & {\left. \Rightarrow x_{FRE} \right. = \frac{D_{PRE}}{4.0}} \\ {\beta_{FRE} = {\frac{x_{field}}{x_{FRE}} = \frac{z_{4}}{z_{3}}}} & {\left. \Rightarrow\beta_{FRE} \right. = \frac{x_{field}}{x_{FRE}}} \\ \; & {\left. \Rightarrow z_{4} \right. = {z_{3} \cdot \beta_{FRE}}} \\ {L = {z_{3} + z_{4}}} & {\left. \Rightarrow z_{3} \right. = \frac{L}{1 + \beta_{FRE}}} \\ {{NA}^{\prime} = \frac{\frac{D_{FRE}}{2}}{z_{3}}} & {\left. \Rightarrow{NA}^{\prime} \right. = \frac{\frac{D_{FRE}}{2}}{z_{3}}} \\ {{\tan (\theta)} = {- \frac{\left( {1 - {Ex}} \right) \cdot {\sin \left( \theta^{\prime} \right)}}{{2\sqrt{Ex}} - {\left( {1 - {Ex}} \right) \cdot {\cos \left( \theta^{\prime} \right)}}}}} & {\left. \Rightarrow{Ex} \right. = {f\left( {{NA}_{source},{NA}^{\prime}} \right)}} \\ {{Ex}_{col} = {\left( \frac{{sk} - {s\; 1}}{{sk} + {s\; 1}} \right)^{2} = \left( \frac{z_{2} - z_{1}}{z_{2} + z_{1}} \right)^{2}}} & {\left. \Rightarrow z_{2} \right. = {z_{1} \cdot \frac{1 + {\sqrt{Ex}}_{col}}{1 - {\sqrt{Ex}}_{col}}}} \\ {{Ex}_{col} = {1 - \frac{R_{col}}{a}}} & {\left. \Rightarrow R_{col} \right. = {\frac{z_{1} + z_{2}}{2} \cdot \left( {1 - {Ex}_{col}} \right)}} \\ {\frac{2}{R_{PRE}} = {\frac{1}{z_{3}} + \frac{1}{z_{4}}}} & {\left. \Rightarrow R_{PRE} \right. = \frac{2 \cdot z_{3} \cdot z_{4}}{z_{3} + z_{4}}} \end{matrix}$

D_(FRE): diameter of the plate with the field raster elements

x_(FRE): length of one field raster element

y_(FRE): width of one field raster element

β_(FRE): magnification ratio of the field raster elements

D_(PRE): diameter of the plate with the pupil raster elements

R_(col): Radius of the elliptical collector

Ex_(col): conical constant of the elliptical collector

NA′: aperture after the collector mirror

With the pregiven specifications the following system parameters can be calculated:

$\begin{matrix} {D_{FRE} = {{2 \cdot L \cdot {NA}_{field}} = {{{2 \cdot 1400}\mspace{14mu} {{mm} \cdot 0.025}} = {70.0\mspace{14mu} {mm}}}}} \\ {x_{FRE} = {\frac{D_{FRE}}{4.0} = {\frac{70.0\mspace{14mu} {mm}}{4.0} = {17.5\mspace{14mu} {mm}}}}} \\ {y_{FRE} = {1.0\mspace{14mu} {mm}}} \\ {\beta_{FRE} = {\frac{x_{field}}{x_{FRE}} = {\frac{105.0\mspace{14mu} {mm}}{17.5\mspace{14mu} {mm}} = 6.0}}} \\ {z_{3} = {\frac{L}{1 + \beta_{FRE}} = {\frac{1400.0\mspace{14mu} {mm}}{1 + 6.0} = {200.0\mspace{14mu} {mm}}}}} \\ {z_{4} = {{z_{3} \cdot \beta_{FRE}} = {{200.0\mspace{14mu} {{mm} \cdot 6.0}} = {1200.0\mspace{14mu} {mm}}}}} \\ {{NA}^{\prime} = {\frac{\frac{D_{DRE}}{2}}{z_{3}} = {\frac{\frac{70.0\mspace{14mu} {mm}}{2}}{200.0\mspace{14mu} {mm}} = 0.175}}} \\ {{Ex}_{col} = {{f\left( {{NA}_{source},{NA}^{\prime}} \right)} = 0.078}} \\ {z_{2} = {{z_{1} \cdot \frac{1 + \sqrt{{Ex}_{col}}}{1 - \sqrt{{Ex}_{col}}}} = {{100.0\mspace{14mu} {{mm} \cdot \frac{1 + \sqrt{0.078}}{1 - \sqrt{0.078}}}} = {585.757\mspace{14mu} {mm}}}}} \\ {\begin{matrix} {R_{col} = {\frac{z_{1} + z_{2}}{2} \cdot \left( {1 - {Ex}_{col}} \right)}} \\ {= {\frac{{330.0\mspace{14mu} {mm}} + {585.757\mspace{14mu} {mm}}}{2} \cdot \left( {1 - 0.078} \right)}} \\ {= {422.164\mspace{14mu} {mm}}} \end{matrix}} \\ {R_{PRE} = {\frac{2 \cdot z_{3} \cdot z_{4}}{z_{3} + z_{4}} = {\frac{2 \cdot 200 \cdot 1200}{200 + 1200} = {342.857\mspace{14mu} {mm}}}}} \end{matrix}$

The total system with the previously indicated dimensions is shown in FIG. 23 up to the reticle plane 208 in the yz section. The central and the two marginal rays are drawn in. Secondary light sources are produced at the plate with the pupil raster elements 206 by the field raster elements 204. The pupil plane of the illumination system is arranged at the plate with the pupil raster elements 206.

The total system is shown in FIG. 24 with an x-z fan of rays, which impinge on the central field raster element.

FIGS. 25 and 26 show the illumination of the reticle with the rectangular field (−52.5 mm<x_(field)<+52.5 mm; −3.0 mm<x_(field)<+3.0 mm). FIG. 25 shows a contour plot, FIG. 26 a—3D presentation. The images of the field raster elements are optimally superimposed in the reticle plane also in the case of the extended secondary light sources, which are produced by the pinch-plasma source, since a pupil raster element plate is used.

In comparison to this, the illumination of the reticle without pupil raster element plate is shown in contour lines and 3D representation in FIGS. 27 and 28. The field raster elements are not imaged sharply. This can be due for example to the extended secondary light sources.

A similar illumination in the field plane can also be achieved if not all of the first raster elements have the same size, e.g. they have a different extension in y-direction, which is also called the scanning direction. In case the second raster elements have an optical effect another possibility to achieve such an illumination in the filed plane is using second raster elements having different optical power.

FIG. 29 shows an intensity profile parallel to the y-axis for x=0.0 for ideally superimposed images of the first raster elements in the image plane. This can be achieved in the case of extended secondary light sources by introducing a pupil raster element plate with second raster elements. In case the images of the first raster elements are ideally superimposed a almost ideal rectangular profile is formed in scanning direction. In case the images are not ideally superimposed e.g. because the secondary light sources are extended and no pupil facets or so called second raster elements are used the profile decomposes and forms a non-rectangular intensity profile in scanning direction. This is shown in FIG. 29 as dotted lines. The gradient of the intensity profile depicted in dashed lines is less than 100% per millimeter.

FIG. 30 shows the scanning energy distribution as a function of the field height. The scan energy is defined as the line integral in scanning direction over the intensity distribution in the reticle plane. The homogeneous scanning energy distribution can be clearly recognized.

In FIG. 31, the illumination of the exit pupil is shown for a object point in the center of the illuminated field. The x- and y-axis represent not the extent in “mm”, but in the sine of the ray angles in the reticle plane. Corresponding to the arrangement of the pupil raster elements, tertiary light sources 3101 are produced in the exit pupil of the illumination system. The maximum aperture amounts to NA_(field)=0.025.

In FIG. 31, 18 tertiary light sources are shown with sin(i_(x))=0. The total energy of the 18 tertiary light sources with sin(i_(x))=0 is plotted in FIG. 32. The tertiary light source 3101 has the number 1 in FIG. 32, the tertiary light source 3105 the number 18. The intensity distribution in the exit pupil has a y-tilt due to the distortion errors introduced by the mirrors tilted about the x-axis. The total energy of the individual tertiary light sources can be adjusted via the reflectivity of the individual raster elements, so that the energy of the tertiary light sources can at least be controlled in a rotational symmetric manner. Another possibility to get a rotational symmetric intensity distribution in the exit pupil of the illumination system is a collector mirror with a spatial dependent reflectivity.

The forms of embodiment of the invention, which use different light sources, for example, are described below.

In FIGS. 33-39, another form of embodiment of the invention is explained with a laser-plasma source as the primary light source. If the field raster elements are not tilted, then the aperture in the reticle plane (NA_(theoretical)=0.025) is given in advance by the ellipsoid or collector mirror. Since the distance from the light source to the ellipsoid or collector mirror should amount to at least 100 mm in order to avoid contaminations, a rigid relationship between structural length and collection efficiency results, as presented in the following table:

TABLE 1 Collection efficiency π (0°-90°): 0°: Beam cone is emitted horizontally Structural Collection 90°: Rays are is emitted in a length L angle θ torus with a mean angle of 90°. 1000 mm 14.3°  2%-12% 2000 mm 28.1°  6%-24% 3000 mm 41.1° 12%-35% 4000 mm 53.1° 20%-45% 5000 mm 90.0° 50%-71%

As can be seen from this, the collection efficiency for a structural length of 3000 mm is maximum 35%.

In order to achieve high collection efficiencies for justifiable structural lengths, in the particularly advantageous form of embodiment of the invention according to FIGS. 35-39, the illumination system comprises a telescope system.

In the represented form of embodiment, a laser-plasma source is used as the primary light source, whereby the field raster element plate is arranged in the convergent beam path of a collector mirror.

In order to reduce the structural length of the illumination system, the illumination system is formed as a telescope system (tele-system). One form of embodiment for forming such a telescope system consists of arranging the field raster elements of the field raster element plate on a collecting surface, and of arranging the pupil raster elements of the pupil raster element plate on a diverging surface. In this way, the surface normal lines of the raster element centers are adapted to the surface normal lines of the supporting surface. As an alternative to this, one can superimpose prismatic components for the raster elements on a planar plate. This would correspond to a Fresnel lens as a carrier surface.

The above-described tele-raster element condenser thus represents a superimposition of the classical telescope system and the raster element condenser. The compression of the diameter of the field raster element plate to the diameter of the pupil raster element plates is possible until the secondary light sources overlap.

In FIGS. 33 to 36, different arrangements are shown schematically, from which the drastic reduction in structural length, which can be achieved with a telescope system, becomes apparent.

FIG. 33 shows an arrangement with collector mirror 300 and laser-plasma light source 302.

With a arrangement of collector mirror, plate 304 with non-tilted field raster elements and plate 306 with non-tilted pupil raster elements, as shown in FIG. 34, the structural length can be shortened only by the zigzag light path. Since the etendue of a point-like source is approximately zero, the field raster element plate 304, is, in fact, fully illuminated, but the pupil raster element plate 306 is illuminated only with individual intensity peaks.

However, now if the raster elements are introduced onto curved supporting surfaces, i.e., the system is configured as a telescope system with a collecting mirror and a diverging mirror, as shown in FIG. 35, then the structural length can be shortened.

In the case of the design according to FIG. 36, the individual raster elements are arranged tilted on a planar carrier surface.

The pupil raster elements of the pupil raster element plate have the task of imaging the field raster elements into the reticle in the case of expanded secondary light sources and to superimpose these images. However, if a sufficiently good point-like light source is present, then the pupil raster element plate is not necessary. The field raster elements can then be introduced either onto the collecting or onto the diverging tele-mirror. If the field raster elements are arranged on the collecting tele-mirror, they can be designed as either concave or planar mirrors. The field raster elements on the diverging telescope mirror can be designed as convex, concave or planar mirrors. Collecting raster elements lead to a real pupil plane; diverging raster elements lead to a virtual pupil plane.

Collector lens 300 and tele-raster element condenser or tele-system 310 produce the pregiven rectangular field illumination of 6 mm×105 mm with correct aperture NA_(field)=0.025 in the image plane of the illumination system. As in the previous examples, with the help of one or more field lenses 314 arranged between tele-raster element condenser 310 and reticle 316, the arc-shaped field is formed and the exit pupil of the illumination system is arranged at the entrance pupil of the projection objective.

An interface plane for the design of the field lens 314 is the plane of the secondary light sources. These secondary light sources must be imaged by the field lens 314 in the entrance pupil of the projection objective forming tertiary light sources. The pupil plane of this imaging is in the reticle plane, in which the arc-shaped field must be produced.

In FIG. 37, a form of embodiment of the invention with only one field mirror 314 is shown. In the form of embodiment with one field mirror, the arc-shaped field can be produced and the entrance pupil of the illumination system can be arranged at the exit pupil of the projection objective. Since reticle 316, however, is illuminated with chief ray angles about 2.97°, there is the danger that the light beam will run back into the illumination system. It is provided in a particularly advantageous form of embodiment to use as field mirrors two grazing-incidence mirrors as shown in FIG. 38. This way, the orientation of the arc-shaped field is inverted and the light beam leaves the illumination system “behind” the field lens 314. With such a configuration the illumination system can be well separated from the projection objective. By using two field mirrors, one also has more degrees of freedom in order to adjust telecentricity and uniformity of the light distribution.

The design of the illumination systems will now be described on the basis of examples of embodiment, whereby the numerical data not will represent a limitation of the system according to the invention.

In the first example of embodiment the illumination system comprises a collector unit, a diverging mirror and a collecting mirror forming a telescope system as well as field lenses, whereby the raster elements are introduced only onto the collecting mirror. All raster elements are identical and lie on a curved supporting surface.

The parameters used are represented in FIG. 39 and are selected as follows below:

-   a. Arc-shaped field: R_(field)=100 mm, segment=60°, field height     ±3.0 mm. -   b. Position of the entrance pupil (Distance between reticle plane     and entrance pupil of the projection objective): z_(EP)=1927.4 mm.     This corresponds to a principal ray angle of i_(PB)=2.97° for y=100     mm. -   c. Aperture at the reticle: NA_(field)=0.025. -   d. Aperture at the source: NA_(source)=0.999. -   e. Distance between the source and the collector mirror: d₁=100.0     mm. -   f. Field raster element size: y_(FRE)=1, x_(FRE)=17.5 mm. -   g. d₃=100 mm. -   h. Compression factor D_(FRE)/D_(PRE)=4:1. -   i. Tilt angle α of the grazing-incidence mirrors, α=80°. -   j. Collector mirror is designed as an ellipsoid with R_(col) and     Ex_(col). -   k. Curvatures of the supporting surfaces R₂ and R₃: spherical. -   l. Curvature R_(FRE) of the field raster element: spherical. -   m. The Field mirrors are torical mirrors without concical     contributions having the curvatures: R_(4x), R_(4y), R_(5x), R_(5y).

FIG. 40 shows an arrangement of a illumination system with collector mirror 300, whereby the first tele-mirror of the telescope system 310 is not structured with field raster elements. The two tele-mirrors of the telescope system 310 show a compression factor of 4:1. The shortening of the structural length due to the telescope system 310 is obvious. With the telescope system, the structural length amounts to 852.3 mm, but without the telescope system, it would amount to 8000.0 mm. In FIG. 41, a fan of rays is shown in the x-z plane for the system according to FIG. 40. Since there are no field raster elements the light source 302 is imaged into the reticle plane.

FIG. 42 in turn represents a fan of rays in the x-z plane, whereby the mirrors of the system according to FIG. 40 are now structured and have field raster elements. Secondary light sources are formed on the second mirror of the telescope system 310 due to the field raster elements on the first mirror of the telescope system 310. In the illuminated field, the light beams from the several field raster elements are correctly overlaid, and a strip with −52.5 mm<x_(field)<+52.5 mm is homogeneously illuminated.

In FIG. 43, the total system up to the entrance pupil 318 of the projection objective is shown. The total system comprises: primary light source 302, collector mirror 300, tele-raster element condenser 310, field mirrors 314, reticle 316 and entrance pupil of the projection objective 318. The drawn-in marginal rays 320, 322 impinge on the reticle and are drawn up to the entrance pupil 318 of the projection objective.

FIG. 44 shows an x-z fan of rays of a configuration according to FIG. 43, which passes through the central field raster element 323. This pencil is in fact physically not meaningful, since it would be vignetted by the second tele-mirror, but shows well the path of the light. One sees on field mirrors 314 how the orientation of the arc-shaped field is rotated through the second field mirror. The rays can run undisturbed into the projection objective (not shown) after reflection at reticle 316.

FIG. 45 shows a fan of rays, which passes through the central field raster element 323 as in FIG. 44, runs along the optical axis and is focused in the center of the entrance pupil.

FIG. 46 describes the illumination of the reticle field with the arc-shaped field produced by the configuration according to FIGS. 40 to 45 (R_(field)=100 mm, segment=60°, field height ±3.0 mm).

In FIG. 47, the scanning energy is shown for an arrangement according to FIGS. 40 to 46. The scanning energy varies between 95% and 100%. The uniformity thus amounts to ±2.5%.

In FIG. 48, the pupil illumination for an object point in the center of the illuminated field is shown. The ray angles are referred to the centroid ray.

Corresponding to the distribution of the field raster elements, circular intensity peaks IP result in the pupil illumination. The obscuration in the center M is caused by the second tele-mirror.

The illumination system described in FIGS. 31 to 48 has the advantage that the collecting angle can be increased to above 90°, since the ellipsoid can also enclose the source.

Further, the structural length can be adjusted by the tele-system. A reduction of structural length is limited due to the angular acceptance of the coating with multilayers and the imaging errors of the surfaces with a high optical power.

For point-like light sources, for example, a laser-plasma sources with a diameter ≦50 μm, an arrangement can be produced with only one plate with field raster elements. Pupil raster elements are in this case not necessary. Then the field raster elements can be introduced onto collecting mirror 350 of the tele-system or onto the diverging second tele-mirror 352. This is shown in FIGS. 48A-48C.

The introduction onto the second tele-mirror 352 has several advantages: In the case of collecting field raster elements, a real pupil plane is formed in “air”, which is freely accessible, as shown in FIG. 48A.

In the case of diverging field raster elements, in fact a virtual pupil plane is formed, which is not accessible, as shown in FIG. 48B. The negative focal length of the field raster elements, however, can be increased.

In order to avoid an obscuration, as shown in FIG. 48C, the mirrors of the tele-system 350, 352, can be tilted toward one another, so that the light beam will be not vignetted by the components.

A second example of embodiment for a illumination system will be described below, which comprises a plate with planar raster elements. The system is particularly characterized by the fact that the collector unit and the plate with the field raster elements form a telescope system. The converging effect of the telescope system is then completely transferred onto the collector mirror, wherein the diverging effect is caused by the tilt angles of the field raster elements.

Such a system has a high system efficiency of 27% with two normal-incidence mirrors (reflectivity≈65%) for the collector mirror and the plate with the field raster elements and two grazing-incidence mirrors (reflectivity≈80%) for the two field mirrors.

Further, a large collecting efficiency can be realized, whereby the collecting steradian amounts to 2π, but which can still be increased.

Based on the zigzag beam path, there are no obscurations in the pupil illumination. In addition, in the described form of embodiment, the structural length can be easily adjusted.

The collector or ellipsoid mirror collects the light radiated from the laser-plasma source and images the primary light source on a secondary light source. A multiple number of individual planar field raster elements are arranged in a tilted manner on a supporting plate. The field raster elements divide the collimated light beam into partial light beams and superimpose these in the reticle plane. The shape of the field raster elements corresponds to the rectangular field of the field to be illuminated. Further, the illumination system has two grazing-incidence toroid mirrors, which form the arc-shaped field, correctly illuminate the entrance pupil of the projection objective, and assure the uniformity of the light distribution in the reticle plane.

In contrast to the first example of embodiment of a tele-system with collector unit as well as a telescope system formed with two additional mirrors, in the presently described form of embodiment, the laser-plasma source alone is imaged by the ellipsoid mirror in the secondary light source. This saves one normal-incidence mirror and permits the use of planar field raster elements. Such a savings presupposes that no pupil raster elements are necessary, i.e., the light source is essentially point-like.

The design will be described in more detail on the basis of FIGS. 49-51.

FIG. 49 shows the imaging of the laser-plasma source 400 through ellipsoid mirror 402. One secondary light source 410 is formed. In the imaging of FIG. 50, a tilted planar mirror 404 deflects the light beam to the reticle plane 406.

In the imaging of FIG. 51, tilted field raster elements 408 are dividing the light beam and superimpose the partial light bundles in the reticle plane 406. In this way, a multiple number of secondary light sources 410 are produced, which are distributed uniformly over the pupil plane. The tilt angles of the individual field raster elements 408 correspond, at the center points of the field raster elements, approximately to the curvatures of a hyperboloid, which would image the laser-plasma source 400 in the reticle plane 406, together with the ellipsoid mirror 402. The diverging effect of the telescope system is thus introduced by the tilt angles of the field raster elements.

In FIG. 52, the abbreviations are drawn in, as they are used in the following system derivation. For better presentation, the system was drawn linearly with refractive components.

The following values are used as a basis for the example of embodiment described below, without the numerical data being seen as a limitation:

-   a. Arc-shaped field radius: R_(field)=100 mm, segment angle 60°,     field width ±3.0 mm, which corresponds to a rectangular field of 105     mm×6 mm. -   b. Aperture at the reticle: NA_(field)=0.025. -   c. Aperture at the source: NA_(source)=0.999. -   d. z₁=100.0 mm. -   e. Structural length L=z₃+z₄=1400 mm. -   f. Number of field raster elements within an x-row=4.

With the following equations the basic configuration of the illumination system can be derived:

$\begin{matrix} {{NA}_{field} = \frac{\frac{D_{FRE}}{2}}{L}} & {\left. \Rightarrow D_{FRe} \right. = {2 \cdot L \cdot {NA}_{field}}} \\ {\frac{D_{PRE}}{x_{FRE}} = 4.0} & {\left. \Rightarrow x_{FRE} \right. = \frac{D_{PRE}}{4.0}} \\ {\beta_{FRE} = {\frac{x_{field}}{x_{FRE}} = \frac{z_{4}}{z_{3}}}} & {\left. \Rightarrow\beta_{FRE} \right. = \frac{x_{field}}{x_{FRE}}} \\ \; & {\left. \Rightarrow z_{4} \right. = {z_{3} \cdot \beta_{FRE}}} \\ {L = {z_{3} + z_{4}}} & {\left. \Rightarrow z_{3} \right. = \frac{L}{1 + \beta_{FRE}}} \\ {{NA}^{\prime} = \frac{\frac{D_{FRE}}{2}}{z_{3}}} & {\left. \Rightarrow{NA}^{\prime} \right. = \frac{\frac{D_{FRE}}{2}}{z_{3}}} \\ {{\tan (\theta)} = {- \frac{\left( {1 - {Ex}} \right) \cdot {\sin \left( \theta^{\prime} \right)}}{{2\sqrt{Ex}} - {\left( {1 - {Ex}} \right) \cdot {\cos \left( \theta^{\prime} \right)}}}}} & {\left. \Rightarrow{Ex} \right. = {f\left( {{NA}_{source},{NA}^{\prime}} \right)}} \\ {{Ex}_{col} = {\left( \frac{{sk} - {s\; 1}}{{sk} + {s\; 1}} \right)^{2} = \left( \frac{z_{2} - z_{1}}{z_{2} + z_{1}} \right)^{2}}} & {\left. \Rightarrow z_{2} \right. = {z_{1} \cdot \frac{1 + {\sqrt{Ex}}_{col}}{1 - {\sqrt{Ex}}_{col}}}} \\ {{Ex}_{col} = {1 - \frac{R_{col}}{a}}} & {\left. \Rightarrow R_{col} \right. = {\frac{z_{1} + z_{2}}{2} \cdot \left( {1 - {Ex}_{col}} \right)}} \end{matrix}$

D_(FRE): diameter of the plate with the field raster elements

x_(FRE): length of one field raster element

y_(FRE): width of one field raster element

β_(FRE): magnification ratio of the imaging of field raster elements

D_(PRE): diameter of the plate with the pupil raster elements

R_(col): curvature of the elliptical collector

Ex_(col): conical constant of the elliptical collector

NA′: aperture after the collector mirror

With the pregiven specifications the following system parameters can be calculated:

$\begin{matrix} \begin{matrix} \begin{matrix} \begin{matrix} \begin{matrix} \begin{matrix} \begin{matrix} \begin{matrix} \begin{matrix} {D_{FRE} = {{2 \cdot L \cdot {NA}_{field}} = {{{2 \cdot 1400}\mspace{14mu} {{mm} \cdot 0.025}} = {70.0\mspace{14mu} {mm}}}}} \\ {x_{FRE} = {\frac{D_{FRE}}{4.0} = {\frac{70.0\mspace{14mu} {mm}}{4.0} = {17.5\mspace{14mu} {mm}}}}} \end{matrix} \\ {y_{FRE} = {1.0\mspace{14mu} {mm}}} \end{matrix} \\ {\beta_{FRE} = {\frac{x_{field}}{x_{FRE}} = {\frac{105.0\mspace{14mu} {mm}}{17.5\mspace{14mu} {mm}} = 6.0}}} \end{matrix} \\ {z_{3} = {\frac{L}{1 + \beta_{FRE}} = {\frac{1400.0\mspace{14mu} {mm}}{1 + 6.0} = {200.0\mspace{14mu} {mm}}}}} \end{matrix} \\ {z_{4} = {{z_{3} \cdot \beta_{FRE}} = {{200.0\mspace{14mu} {{mm} \cdot 6.0}} = {1200.0\mspace{14mu} {mm}}}}} \end{matrix} \\ {{NA}^{\prime} = {\frac{\frac{D_{DRE}}{2}}{z_{3}} = {\frac{\frac{70.0\mspace{14mu} {mm}}{2}}{200.0\mspace{14mu} {mm}} = 0.175}}} \end{matrix} \\ {{Ex}_{col} = {{f\left( {{NA}_{source},{NA}^{\prime}} \right)} = 0.695}} \end{matrix} \\ {z_{2} = {{z_{1} \cdot \frac{1 + \sqrt{{EX}_{col}}}{1 - \sqrt{{Ex}_{col}}}} = {{100.0\mspace{14mu} {{mm} \cdot \frac{1 + \sqrt{0.695}}{1 - \sqrt{0.695}}}} = {1101.678\mspace{14mu} {mm}}}}} \end{matrix} \\ \begin{matrix} {R_{col} = {\frac{z_{1} + z_{2}}{2} \cdot \left( {1 - {Ex}_{col}} \right)}} \\ {= {\frac{{100.0\mspace{14mu} {mm}} + {1101.678\mspace{14mu} {mm}}}{2} \cdot \left( {1 - 0.695} \right)}} \\ {= {183.357\mspace{14mu} {mm}}} \end{matrix} \end{matrix}$

The field mirrors are constructed similar to the case of the first example of embodiment of a illumination system, i.e., two toroid mirrors are again used as field mirrors.

In FIGS. 53-58, the propagation of the light rays is shown in a illumination system according to the previously given parameters as an example.

In FIG. 53, the ray propagation is shown for an ellipsoid mirror 402, which is designed for a source aperture NA=0.999 and which images the primary light source 400 on a secondary light source 410.

In the form of embodiment according to FIG. 54, a planar mirror 404 is arranged at the position of the field raster element plate, which reflects the light beam. The rays are propagated up to the reticle plane 406.

Finally, in FIG. 55, the construction according to the invention is shown, in which mirror 404 is replaced by the field raster element plate 412. A fan of rays is depicted, wherein each ray goes through the center of the individual field raster elements. These rays intersect on the optical axis in the reticle plane 406.

In this configuration the primary light source 400 is arranged in the object plane of the collector mirror 402, wherein the secondary light source 410 is arranged in the image plane of the collector mirror 402. If the collector unit consists only of one collector mirror 402 the image-side principal plane of the collector unit is located at the vertex of the collector mirror 402. The optical distance between the vertex of the collector mirror 402 and the secondary light source 410 is in this configuration equal to the sum of the optical distance between the vertex of the collector mirror 402 and the plate 412 with the field raster elements and the optical distance between the plate 412 with the field raster elements and the secondary light source 410. If the refraction index is equal to 1.0, the optical distance is equal to the geometrical distance.

FIG. 56 finally shows the total illumination system up to entrance pupil 414 of the projection objective with two field mirrors 416. The marginal rays 418, 420 strike on reticle 406 and are further propagated up to the entrance pupil 414 of the projection objective.

In FIG. 57, an x-z fan of rays is depicted for the system of FIG. 56, and this fan strikes the central field raster element 422. The rays illuminate the arc-shaped field on reticle 406 with the correct orientation.

In FIG. 58, in addition, the entrance pupil 424 of the projection objective is represented. The depicted rays are propagated along the optical axis and are focused in the center of the entrance pupil. The primary light source 400 is imaged into the secondary light source 410 by the collector mirror 402, wherein the field mirrors 416 image the secondary light source 410 into a tertiary light source in the center of the entrance pupil 424 of the projection objective.

In FIG. 59, the illumination of the reticle is shown with an arc-shaped field (R_(field)=100 mm, segment=60°, field height ±3.0 mm), which is based on an illumination arrangement according to FIGS. 52-58.

The integral scanning energy is shown in FIG. 60. The integral scan energy varies between 100% and 105%. The uniformity or homogeneity thus amounts to ±2.5%.

FIG. 61 represents the pupil illumination of the above-described system for an object point in the center of the illuminated field. The sines of the ray angles are referred to the direction of the centroid ray. Corresponding to the field raster element distribution, a distribution of tertiary light sources 6101 is produced in the pupil illumination. The tertiary light sources 6101 are uniformly distributed. There are no center obscurations, since in the case of the described second form of embodiment, the mirrors are arranged in zigzag configuration.

In FIG. 62, a profile of the intensity distribution at x=0 mm is shown in the scan direction with the use of two different laser-plasma sources. Whereas without the pupil raster elements for the 50-μm source, the desired rectangular profile is obtained, the 200-μm source shows at the edges a clear blurring. This source can no longer be considered point-like. The use of pupil raster elements, such as, for example, in the case of the pinch-plasma source, is necessary for the correct imaging of the field raster elements into the reticle plane.

In FIGS. 63A+63B two possibilities are shown for the formation of the field raster element plate. In FIG. 63A, the raster elements 500 are arranged on a curved supporting surface 502. Thus the inclination of the raster elements corresponds to the slope of the supporting surface. Such plates are described, for example, in the case of the first form of embodiment with a collector mirror and a telescope system comprising two mirrors.

If the field raster elements 500 are shaped in planar manner, such as, for example, in the case of the second form of embodiment that is described, in which collector unit and field raster element plate are combined into a telescope system, then the individual field raster elements are arranged under a pregiven tilt angle on the raster element plate 504. Depending on the distribution of the tilt angles on the plate, one obtains either collecting or diverging effects. A plate with a diverging effect is illustrated.

Of course, raster element plates with planar field raster elements can be used also in systems according to the first example of embodiment with a collector unit and two tele-mirrors. In the case of such a system, the raster elements are then tilted onto one of the mirrors such that a diverging effect is produced and onto the other in such a way that a collecting effect is produced.

FIG. 64 shows a form of embodiment of the invention, which is designed as a refractive system with lenses for wavelengths, for example, of 193 nm or 157 nm. The system comprises a light source 600, a collector lens 602, as well as a field raster element plate 604 and a pupil raster element plate 606. Prisms 608 arranged in front of the field raster elements serve for adjusting the light path between the field raster element plate 604 and the pupil raster element plate 606.

FIG. 65 shows another embodiment for a purely refractive system in a schematically view. The beam cone of the light source 6501 is collected by the aspherical collector lens 6503 and is directed to the plate with the field raster elements 6509. The collector lens 6503 is designed to generate an image 6505 of the light source 6501 at the plate with the pupil raster elements 6515 as shown with the dashed lines if the plate with the field raster elements 6509 is not in the beam path. Therefore without the plate with the field raster elements 6509 one secondary light source 6505 would be produced at the plate with the pupil raster elements. This imaginary secondary light source 6505 is divided into a plurality of secondary light sources 6507 by the field raster elements 6509 formed as field prisms 6511. The arrangement of the secondary light sources 6507 at the plate with the pupil raster elements 6515 is produced by the deflection angles of the field prisms 6511. These field prisms 6511 have rectangular surfaces and generate rectangular light bundles. However, they can have any other shape. The pupil raster elements 6515 are arranged nearby each of the secondary light sources 6507 to image the corresponding field raster elements 6509 into the reticle plane 6529 and to superimpose the rectangular images of the field raster elements 6509 in the field 6531 to be illuminated. The pupil raster elements 6515 are designed as combinations of a pupil prism 6517 and a pupil lenslet 6519 with positive optical power. The pupil prisms 6517 deflect the incoming ray bundles to superimpose the images of the field raster elements 6509 in the reticle plane 6529. The pupil lenslets 6519 are designed together with the field lens 6521 to image the field raster elements 6509 into the reticle plane 6529. Therefore with the prismatic deflection of the ray bundles at the field raster elements 6509 and pupil raster elements 6515 an arbitrary assignment between field raster elements 6509 and pupil raster elements 6515 is possible. The pupil prisms 6517 and the pupil lenslets 6519 can also be made integrally to form a pupil raster element 6515 with positive and prismatic optical power. The field lens 6521 images the secondary light sources 6507 into the exit pupil 6533 of the illumination system forming tertiary light sources 6535 there.

FIG. 66 shows another embodiment for a purely refractive system in a schematically view. Corresponding elements have the same reference numbers as those in FIG. 65 increased by 100. Therefore, the description to these elements is found in the description to FIG. 65. The aspherical collector lens 6603 is designed to focus the light rays of the light source 6601 in a plane 6605 which is arranged behind the plate with the pupil raster elements 6615 as indicated by the dashed lines. Therefore the field raster elements 6609 have a positive optical power to produce the secondary light sources 6607 at the plate with the pupil raster elements 6615. The field raster elements 6609 are designed as combinations of a field prism 6611 and a field lenslet 6613. The field prisms 6611 deflect the incoming ray bundles to the corresponding secondary light sources 6607. The field lenslets 6613 are designed to generate the secondary light sources 6607 at the corresponding pupil raster elements 6615. The field prisms 6611 and the field lenslets 6613 can also be made integrally to form field raster elements 6609 with positive and prismatic optical power.

FIG. 67 shows another embodiment for a purely refractive system in a schematically view. Corresponding elements have the same reference numbers as those in FIG. 66 increased by 100. Therefore, the description to these elements is found in the description to FIG. 66. The aspheric collector lens 6703 is designed to focus the light rays of the light source 6701 in a plane 6705 which is arranged between the plate with the field raster elements 6709 and the plate with the pupil raster elements 6715 as indicated by the dashed lines. Therefore the field raster elements 6709 have negative optical power to produce the secondary light sources 6707 at the plate with the pupil raster elements 6715. The field raster elements 6709 are designed as combinations of a field prism 6711 and a field lenslet 6713. The field prisms 6711 deflect the incoming ray bundles to the corresponding secondary light sources 6707. The field lenslets 6713 are designed to generate the secondary light sources 6707 at the corresponding pupil raster elements 6715. The field prisms 6711 and the field lenslets 6713 can also be made integrally to form field raster elements 6709 with negative and prismatic optical power.

FIG. 68 shows another embodiment for a purely refractive system in a schematically view. Corresponding elements have the same reference numbers as those in FIG. 67 increased by 100. Therefore, the description to these elements is found in the description to FIG. 67. The aspheric collector lens 6803 is designed to generate a parallel light bundle. Wherein in FIGS. 65 to 67 the plate with the field raster elements is arranged in a convergent beam path, the plate with the field raster elements 6809 in FIG. 68 is arranged in a parallel beam path. The field raster elements 6809 are designed as combinations of a field prism 6811 and a field lenslet 6813. The field prisms 6811 deflect the incoming ray bundles to the corresponding secondary light sources 6807. The field lenslets 6813 are designed to generate the secondary light sources 6807 at the corresponding pupil raster elements 6815. They have positive optical power and a focal length that corresponds to the distance between the field raster elements 6809 and the pupil raster elements 6815. Since the light source 6801 is a point-like source, also the secondary light sources 6807 are point-like. Therefore, the pupil raster elements 6815 are designed as prisms 6817.

FIG. 69 shows another embodiment for a purely refractive system in a schematically view. Corresponding elements have the same reference numbers as those in FIG. 66 increased by 300. Therefore, the description to these elements is found in the description to FIG. 66. The aspheric collector lens 6903 is designed to focus the light rays of the light source 6601 in a plane 6905 which is arranged in front of the plate with the field raster elements 6909 as indicated by with the dashed lines. Nearby this image of the light source a transmissions filter 6937 is arranged. This filter can also be used to select the used wavelength range. In the plane 6905 also a shutter can be arranged. The field raster elements 6909 have a positive optical power to produce the secondary light sources 6907 at the plate with the pupil raster elements 6915.

FIG. 70 shows an embodiment for a purely reflective system in a schematically view. Corresponding elements have the same reference numbers as those in FIG. 69 increased by 100. Therefore, the description to these elements is found in the description to FIG. 69. The beam cone of the light source 7001 is collected by the ellipsoidal collector mirror 7003 and is directed to the plate with the field raster elements 7009. The collector mirror 7003 is designed to generate an image 7005 of the light source 7001 between the plate with the field raster elements 7009 and the plate with the pupil raster elements 7015 if the plate with the field raster elements 7009 would be a planar mirror as indicated by the dashed lines. The convex field raster elements 7009 are designed to generate point-like secondary light sources 7007 at the pupil raster elements 7015, since the light source 7001 is also point-like. Therefore the pupil raster elements 7015 are designs as planar mirrors. Since the intensity at the point-like secondary light sources 7007 is very high, the planar pupil raster elements 7015 can alternatively be arranged defocused from the secondary light sources 7007. The distance between the secondary light sources 7007 and the pupil raster elements 7015 should not exceed 20% of the distance between the field raster elements and the pupil raster elements. The pupil raster elements 7015 are tilted to superimpose the images of the field raster elements 7009 together with the field lens 7021 formed as the field mirrors 7023 and 7027 in the field 7031 to be illuminated. Both, the field raster elements 7009 and the pupil raster elements 7015 are tilted. Therefore the assignment between the field raster elements 7009 and pupil raster elements 7015 is defined by the user. In the embodiment of FIG. 70 the field raster elements 7009 at the center of the plate with the field raster elements 7009 correspond to the pupil raster elements 7015 at the border of the plate with the pupil raster elements 7015 and vice versa. The tilt angles and the tilt axes of the field raster elements are determined by the directions of the incoming ray bundles and by the positions of the corresponding pupil raster elements 7015. Since for each field raster element 7009 the tilt angle and the tilt axis is different, also the planes of incidence defined by the incoming and reflected centroid rays are not parallel. The tilt angles and the tilt axes of the pupil raster elements 7015 are determined by the positions of the corresponding field raster elements 7009 and the requirement that the images of the field raster elements 7009 has to be superimposed in the field 7031 to be illuminated. The concave field mirror 7023 images the secondary light sources 7007 into the exit pupil 7033 of the illumination system forming tertiary light sources 7035, wherein the convex field mirror 7027 being arranged at grazing incidence transforms the rectangular images of the rectangular field raster elements 7009 into arc-shaped images.

FIG. 71 shows another embodiment for a purely reflective system in a schematically view. Corresponding elements have the same reference numbers as those in FIG. 70 increased by 100. Therefore, the description to these elements is found in the description to FIG. 70. In this embodiment the light source 7101 and therefore also the secondary light sources 7107 are extended. The pupil raster elements 7115 are designed as concave mirrors to image the field raster elements 7109 into the image plane 7129. It is also possible to arrange the pupil raster elements 7115 not at the secondary light sources 7107, but defocused. The influence of the defocus on the imaging of the field raster elements 7109 has to be consider in the optical power of the pupil raster elements.

FIG. 72 shows in a schematic view the imaging of one field raster element 7209 into the reticle plane 7229 forming an image 7231 and the imaging of the corresponding secondary light source 7207 into the exit pupil 7233 of the illumination system forming a tertiary light source 7235. Corresponding elements have the same reference numbers as those in FIG. 70 increased by 200. Therefore, the description to these elements is found in the description to FIG. 70.

The field raster elements 7209 are rectangular and have a length X_(FRE) and a width Y_(FRE). All field raster elements 7209 are arranged on a nearly circular plate with a diameter D_(FRE). They are imaged into the image plane 7229 and superimposed on a field 7231 with a length X_(field) and a width Y_(field), wherein the maximum aperture in the image plane 7229 is denoted by NA_(field). The field size corresponds to the size of the object field of the projection objective, for which the illumination system is adapted.

The plate with the pupil raster elements 7215 is arranged in a distance of Z₃ from the plate with the field raster elements 7209. The shape of the pupil raster elements 7215 depends on the shape of the secondary light sources 7207. For circular secondary light sources 7207 the pupil raster elements 7215 are circular or hexagonal for a dense packaging of the pupil raster elements 7215. The diameter of the plate with the pupil raster elements 7215 is denoted by D_(PRE).

The pupil raster elements 7215 are imaged by the field lens 7221 into the exit pupil 7233 having a diameter of D_(EP). The distance between the image plane 7229 of the illumination system and the exit pupil 7233 is denoted with Z_(EP). Since the exit pupil 7233 of the illumination system corresponds to the entrance pupil of the projection objective, the distance Z_(EP) and the diameter D_(EP) are predetermined values. The entrance pupil of the projection objective is typically illuminated up to a user-defined filling ratio σ.

The data for a preliminary design of the illumination system can be calculated with the equations and data given below. The values for the parameters are typical for a EUV projection exposure apparatus. But there is no limitation to these values. Wherein the schematic design is shown for a refractive linear system it can be easily adapted for reflective systems by exchanging the lenses with mirrors.

The field 7231 to be illuminated is defined by a segment of an annulus. The Radius of the annulus is

R_(field)=138 mm.

The length and the width of the segment are

X _(field)=88 mm, Y_(field)=8 mm

Without the field-forming field mirror, which transforms the rectangular images of the field raster elements into arc-shaped images, the field to be illuminated is rectangular with the length and width defined by the segment of the annulus.

The distance from the image plane to the exit pupil is

Z_(EP)=1320 mm.

The object field of the projection objective is an off-axis field. The distance between the center of the field and the optical axis of the projection objective is given by the radius R_(field). Therefore the incidence angle of the centroid ray in the center of the field is 6°.

The aperture at the image plane of the projection objective is NA_(wafer)=0.25. For a reduction projection objective with a magnification ratio of β_(proj)=−0.25 and a filling ratio of σ=0.8 the aperture at the image plane of the illumination system is

${NA}_{field} = {{\sigma \cdot \frac{{NA}_{wafer}}{4}} = 0.05}$ D_(EP) = 2  tan [arcsin (NA_(field))] ⋅ Z_(EP) ≈ 2NA_(EP) ⋅ Z_(EP) ≈ 132  mm

The distance Z₃ between the field raster elements and the pupil raster elements is related to the distance Z_(EP) between the image plane and the exit pupil by the depth magnification α:

Z _(EP) =α·Z ₃

The size of the field raster elements is related to the field size by the lateral magnification β_(field):

X _(field)=β_(field) ·X _(FRE)

Y _(field)=β_(field) ·Y _(FRE)

The diameter D_(PRE) of the plate with the pupil raster elements and the diameter D_(EP) of the exit pupil are related by the lateral magnification β_(pupil):

D _(EP)=β_(pupil) ·D _(PRE)

The depth magnification ox is defined by the product of the lateral magnifications β_(field) and β_(pupil):

α=β_(field)·β_(pupil)

The number of raster elements being superimposed at the field is set to 200. With this high number of superimposed images the required field illumination uniformity can be achieved.

Another requirement is to minimize the incidence angles on the components. For a reflective system the beam path is bent at the plate with the field raster elements and at the plate with the pupil raster elements. The bending angles and therefore the incidence angles are minimum for equal diameters of the two plates:

D_(PRE) = D_(FRE) $\quad\begin{matrix} {{200 \cdot X_{PRE} \cdot Y_{PRE}} = {200 \cdot \frac{X_{field} \cdot Y_{field}}{\beta_{field}^{2}}}} \\ {= \frac{D_{EP}^{2}}{\beta_{pupil}^{2}}} \\ {= {\frac{\beta_{field}^{2}}{\alpha^{2}}D_{EP}^{2}}} \end{matrix}$

The distance Z₃ is set to Z₃=900 mm. This distance is a compromise between low incidence angles and a reduced overall length of the illumination system.

$\alpha = {\frac{Z_{EP}}{Z_{3}} = 1.47}$

Therefore

$\begin{matrix} {{\beta_{field}} \approx \sqrt[4]{\frac{200 \cdot X_{field} \cdot Y_{field}}{D_{EP}^{2}}\alpha^{2}} \approx 2.05} \\ {{\beta_{pupil}} \approx \frac{\alpha}{\beta_{field}} \approx 0.7} \\ {D_{FRE} = {D_{PRE} = {{\frac{\beta_{field}}{\alpha}D_{EP}} \approx {200\mspace{14mu} {mm}}}}} \\ {X_{FRE} = {\frac{X_{field}}{\beta_{field}} \approx {43\mspace{14mu} {mm}}}} \\ {Y_{FRE} = {\frac{Y_{field}}{\beta_{field}} \approx {4\mspace{14mu} {mm}}}} \end{matrix}$

With these values the principal layout of the illumination system is known.

In a next step the field raster elements 7309 have to be distributed on the plate as shown in FIG. 73. The two-dimensional arrangement of the field raster elements 7309 is optimized for efficiency. Therefore the distance between the field raster elements 7309 is as small as possible. Field raster elements 7309, which are only partially illuminated, will lead to uniformity errors of the intensity distribution in the image plane, especially in the case of a restricted number of field raster elements 7309. Therefore only these field raster elements 7309 are imaged into the image plane which are illuminated almost completely. FIG. 73 shows a possible arrangement of 216 field raster elements 7309. The solid line 7339 represents the border of the circular illumination of the plate with the field raster elements 7309. Therefore the filling efficiency is approximately 90%. The rectangular field raster elements 7309 have a length X_(FRE)=46.0 mm and a width Y_(FRE)=2.8 mm. All field raster elements 7309 are inside the circle 7339 with a diameter of 200 mm. The field raster elements 7309 are arranged in 69 rows 7341 being arranged one among another. The field raster elements 7309 in the rows 7341 are attached at the smaller y-side of the field raster elements 7309. The rows 7341 consist of one, two, three or four field raster elements 7309. Some rows 7341 are displaced relative to the adjacent rows 7341 to distribute the field raster elements 7309 inside the circle 7339. The distribution is symmetrical to the y-axis.

FIG. 74 shows the arrangement of the pupil raster elements 7415. They are arranged on a distorted grid to compensate for distortion errors of the field lens. If this distorted grid of pupil raster elements 7415 is imaged into the exit pupil of the illumination system by the field lens a undistorted regular grid of tertiary light sources will be generated. The pupil raster elements 7415 are arranged on curved lines 7443 to compensate the distortion introduced by the field-forming field mirror. The distance between adjacent pupil raster elements 7415 is increased in y-direction to compensate the distortion introduced by field mirrors being tilted about the x-axis. Therefore the pupil raster elements 7415 are not arranged inside a circle. The size of the pupil raster elements 7415 depends on the source size or source etendue. If the source etendue is much smaller than the required etendue in the image plane, the secondary light sources will not fill the plate with the pupil raster elements 7415 completely. In this case the pupil raster elements 7415 need only to cover the area of the secondary light sources plus some overlay to compensate for source movements and imaging aberrations of the collector-field raster element unit. In FIG. 74 circular pupil raster elements 7415 are shown.

Each field raster element 7309 corresponds to one of the pupil raster elements 7415 according to an assignment table and is tilted to deflect an incoming ray bundle to the corresponding pupil raster element 7415. A ray coming from the center of the light source and intersecting the field raster element 7309 at its center is deflected to intersect the center of the corresponding pupil raster element 7415. The tilt angle and tilt axis of the pupil raster element 7415 is designed to deflect this ray in such a way, that the ray intersects the field in its center.

The field lens images the plate with the pupil raster elements into the exit pupil and generates the arc-shaped field with the desired radius R_(field). For R_(field)=138 mm, the field forming gracing incidence field mirror has only low negative optical power. The optical power of the field-forming field mirror has to be negative to get the correct orientation of the arc-shaped field. Since the magnification ratio of the field lens has to be positive, another field mirror with positive optical power is required. Wherein for apertures NA_(field) lower than 0.025 the field mirror with positive optical power can be a grazing incidence mirror, for higher apertures the field mirror with positive optical power should be a normal incidence mirror.

FIG. 75 shows a schematic view of a embodiment comprising a light source 7501, a collector mirror 7503, a plate with the field raster elements 7509, a plate with the pupil raster elements 7515, a field lens 7521, an image plane 7529 and an exit pupil 7533. The field lens 7521 has one normal-incidence mirror 7523 with positive optical power for pupil imaging and one grazing-incidence mirror 7527 with negative optical power for field shaping. Exemplary for the imaging of all secondary light sources, the imaging of one secondary light source 7507 into the exit pupil 7533 forming a tertiary light source 7535 is shown. The optical axis 7545 of the illumination system is not a straight line but is defined by the connection lines between the single components being intersected by the optical axis 7545 at the centers of the components. Therefore, the illumination system is a non-centered system having an optical axis 7545 being bent at each component to get a beam path free of vignetting. There is no common axis of symmetry for the optical components. Projection objectives for EUV exposure apparatus are typically centered systems with a straight optical axis and with an off-axis object field. The optical axis 7547 of the projection objective is shown as a dashed line. The distance between the center of the field 7531 and the optical axis 7547 of the projection objective is equal to the field radius R_(field). The pupil imaging field mirror 7523 and the field-forming field mirror 7527 are designed as on-axis toroidal mirrors, which means that the optical axis 7545 paths through the vertices of the on-axis toroidal mirrors 7523 and 7527.

In another embodiment as shown in FIG. 76, a telescope objective in the field lens 7621 comprising the field mirror 7623 with positive optical power, the field mirror 7625 with negative optical power and the field mirror 7627 is applied to reduce the track length. Corresponding elements have the same reference numbers as those in FIG. 75 increased by 100. Therefore, the description to these elements is found in the description to FIG. 75. The field mirror 7625 and the field mirror 7623 of the telescope objective in FIG. 74 are formed as an off-axis Cassegrainian configuration. The telescope objective has an object plane at the secondary light sources 7607 and an image plane at the exit pupil 7633 of the illumination system. The pupil plane of the telescope objective is arranged at the image plane 7629 of the illumination system. In this configuration, having five normal-incidence reflections at the mirrors 7603, 7609, 7615, 7625 and 7623 and one grazing-incidence reflection at the mirror 7627, all mirrors are arranged below the image plane 7629 of the illumination system. Therefore, there is enough space to install the reticle and the reticle support system.

In FIG. 77 a detailed view of the embodiment of FIG. 76 is shown. Corresponding elements have the same reference numbers as those in FIG. 76 increased by 100. Therefore, the description to these elements is found in the description to FIG. 76. The components are shown in a y-z-sectional view, wherein for each component the local co-ordinate system with the y- and z-axis is shown. For the collector mirror 7703 and the field mirrors 7723, 7725 and 7727 the local co-ordinate systems are defined at the vertices of the mirrors. For the two plates with the raster elements the local co-ordinate systems are defined at the centers of the plates. In table 2 the arrangement of the local co-ordinate systems with respect to the local co-ordinate system of the light source 7701 is given. The tilt angles α, β and γ about the x-, y- and z-axis are defined in a right-handed system.

TABLE 2 Co-ordinate systems of vertices of mirrors X [mm] Y[mm] Z[mm] α [°] β [°] γ[°] Light source 7701 0.0 0.0 0.0 0.0 0.0 0.0 Collector mirror 0.0 0.0 125.0 0.0 0.0 0.0 7703 Plate with field 0.0 0.0 −975.0 10.5 180.0 0.0 raster elements 7709 Plate with pupil 0.0 −322.5 −134.8 13.5 0.0 180.0 raster elements 7715 Field mirror 7725 0.0 508.4 −1836.1 −67.8 0.0 180.0 Field mirror 7723 0.0 204.8 −989.7 −19.7 0.0 180.0 Field mirror 7727 0.0 −163.2 −2106.2 49.4 180.0 0.0 Image plane 7731 0.0 −132.1 −1820.2 45.0 0.0 0.0 Exit pupil 7733 0.0 −1158.1 −989.4 45.0 0.0 0.0

The surface data are given in table 3. The radius R and the conical constant K define the surface shape of the mirrors according to the formula

${z = \frac{\frac{1}{R}h^{2}}{1 + \sqrt{1 - {\left( {1 + K} \right)\left( \frac{1}{R} \right)^{2}h^{2}}}}},$

wherein h is the radial distance of a surface point from the z-axis.

TABLE 3 Optical data of the components Field Pupil Collector raster raster Field Field Field mirror element element mirror mirror mirror 7703 7709 7715 7725 7723 7727 R [mm] −235.3 ∞ −1239.7 −534.7 −937.7 −65.5 K −0.77855 0.0 0.0 −0.0435 −0.0378 −1.1186 Focal — ∞ 617.6 −279.4 477.0 −757.1 length f [mm]

The light source 7701 in this embodiment is a Laser-Produced-Plasma source having a diameter of approximately 0.3 mm generating a beam cone with an opening angle of 83°. To decrease the contamination of the collector mirror 7703 by debris of the source 7701 the distance to the collector mirror 7703 is set to 125 mm.

The collector mirror 7703 is an elliptical mirror, wherein the light source 7701 is arranged in the first focal point of the ellipsoid and wherein the plate with the pupil raster elements 7715 is arranged in the second focal point of the ellipsoid.

Therefore the field raster elements 7709 can be designed as planar mirrors. The distance between the vertex of the collector mirror 7703 and the center of the plate with the field raster elements 7709 is 1100 mm. The field raster elements 7709 are rectangular with a length X_(FRE)=46.0 mm and a width Y_(FRE)=2.8 mm. The arrangement of the field raster elements is shown in FIG. 73. The tilt angles and tilt axis are different for each field raster element 7709, wherein the field raster elements are tilted to direct the incoming ray bundles to the corresponding pupil raster elements 7715. The tilt angles are in the range of −4° to 4°. The mean incidence angle of the rays on the field raster elements is 10.5°. Therefore the field raster elements 7709 are used at normal incidence.

The plate with the pupil raster elements 7715 is arranged in a distance of 900 mm from the plate with the field raster elements 7709. The pupil raster elements 7715 are concave mirrors. The arrangement of the pupil raster elements 7715 is shown in FIG. 72. The tilt angles and tilt axis are different for each pupil raster element 7715, wherein the pupil raster elements 7715 are tilted to superimpose the images of the field raster elements 7709 in the image plane 7731. The tilt angles are in the range of −4° to 4°. The mean incidence angle of the rays on the pupil raster elements 7715 is 7.5°. Therefore the pupil raster elements 7715 are used at normal incidence.

The field mirror 7725 is a convex mirror. The used area of this mirror defined by the incoming rays is an off-axis segment of a rotational symmetric conic surface. The mirror surface is drawn in FIG. 77 from the vertex up to the used area as dashed line. The distance between the center of the plate with the pupil raster elements 7715 and the center of the used area on the field mirror 7725 is 1400 mm. The mean incidence angle of the rays on the field mirror 7725 is 12°. Therefore the field mirror 7725 is used at normal incidence.

The field mirror 7723 is a concave mirror. The used area of this mirror defined by the incoming rays is an off-axis segment of a rotational symmetric conical surface. The mirror surface is drawn in FIG. 77 from the vertex up to the used area as dashed line. The distance between the center of the used area on the field mirror 7725 and the center of the used area on the field mirror 7723 is 600 mm. The mean incidence angle of the rays on the field mirror 7723 is 7.5°. Therefore the field mirror 7723 is used at normal incidence.

The field mirror 7727 is a convex mirror. The used area of this mirror defined by the incoming rays is an off-axis segment of a rotational symmetric conic surface. The mirror surface is drawn in FIG. 77 from the vertex up to the used area as dashed line. The distance between the center of the used area on the field mirror 7723 and the center of the used area on the field mirror 7727 is 600 mm. The mean incidence angle of the rays on the field mirror 7727 is 78°. Therefore the field mirror 7727 is used at grazing incidence. The distance between the field mirror 7727 and the image plane 7731 is 300 mm.

In another embodiment the field mirror and the field mirror are replaced with on-axis toroidal mirrors. The vertices of these mirrors are arranged in the centers of the used areas. The convex field mirror has a radius R_(y)=571.3 mm in the y-z-section and a radius R_(x)=546.6 mm in the x-z-section. This mirror is tilted about the local x-axis about 12° to the local optical axis 7745 defined as the connection lines between the centers of the used areas of the mirrors. The concave field mirror has a radius R_(y)=−962. 14 mm in the y-z-section and a radius R_(x)=−945. 75 mm in the x-z-section. This mirror is tilted about the local x-axis about 7.5° to the local optical axis 7745.

FIG. 78 shows the illuminated arc-shaped area in the image plane 7731 of the illumination system presented in FIG. 77. The orientation of the y-axis is defined in FIG. 77. The solid line 7849 represents the 50%-value of the intensity distribution, the dashed line 7851 the 10%-value. The width of the illuminated area in y-direction is constant over the field. The intensity distribution is the result of a simulation done with the optical system given in table 2 and table 3.

FIG. 79 shows the illumination of the exit pupil 7733 for an object point in the center (x=0 mm; y=0 mm) of the illuminated field in the image plane 7731. The arrangement of the tertiary light sources 7935 corresponds to the arrangement of the pupil raster elements 7715, which is presented in FIG. 74. Wherein the pupil raster elements in FIG. 74 are arranged on a distorted grid, the tertiary light sources 7935 are arranged on a undistorted regular grid. It is obvious in FIG. 79, that the distortion errors of the imaging of the secondary light sources due to the tilted field mirrors and the field-shaping field mirror are compensated. The shape of the tertiary light sources 7935 is not circular, since the light distribution in the exit pupil 7733 is the result of a simulation with a Laser-Plasma-Source which was not spherical but ellipsoidal. The source ellipsoid was oriented in the direction of the local optical axis. Therefore also the tertiary light sources are not circular, but elliptical.

Due to the mixing of the light channels and the user-defined assignment between the field raster elements and the pupil raster elements, the orientation of the tertiary light sources 7935 is different for nearby each tertiary light source 7935. Therefore, the planes of incidence of at least two field raster elements have to intersect each other. The plane of incidence of a field raster element is defined by the centroid ray of the incoming bundle and its corresponding deflected ray.

FIG. 80 shows another embodiment in a schematic view. Corresponding elements have the same reference numbers as those in FIG. 76 increased by 400. Therefore, the description to these elements is found in the description to FIG. 76. In this embodiment the beam path between the plate with the pupil raster elements 8015 and the field mirror 8025 is crossing the beam path from the collector mirror 8003 to the plate with the field raster elements 8009. With this arrangement it is possible to have light sources 8001 emitting a beam cone horizontally and to arrange the reticle horizontally in the image plane 8029 simultaneously.

FIG. 81 shows a similar embodiment to the one of FIG. 80 in a detailed view. Corresponding elements have the same reference numbers as those in FIG. 80 increased by 100. Therefore, the description to these elements is found in the description to FIG. 80. The definition of the local co-ordinate systems is the same as in FIG. 77. The positions of the local co-ordinate systems are given in table 4.

TABLE 4 Co-ordinate systems of vertices of mirrors X [mm] Y[mm] Z[mm] α [°] β [°] γ[°] Light source 8101 0.0 0.0 0.0 0.0 0.0 0.0 Collector mirror 0.0 0.0 100.0 0.0 0.0 0.0 8103 Plate with field 0.0 0.0 −10.0 10.5 180.0 0.0 raster elements 8109 Plate with pupil 0.0 −322.5 −159.8 31.0 0.0 180.0 raster elements 8115 Field mirror 8125 0.0 1395.9 −1110.3 −20.3 0.0 180.0 Field mirror 8123 0.0 746.5 −645.4 13.6 0.0 180.0 Field mirror8127 0.0 1053.2 −1784.2 86.3 180.0 0.0 Image plane 8131 0.0 906.0 −1537.1 82.0 0.0 0.0 Exit pupil 8135 0.0 −413.5 −1491.0 82.0 0.0 0.0 The surface data are given in table 5.

TABLE 5 Optical data of the components Field Pupil Collector raster raster Field Field Field mirror element element mirror mirror mirror 8103 8109 8115 8125 8123 8127 R [mm] −200.00 −1800.0 −1279.7 −588.9 −957.1 −65.5 K −1.0 0.0 0.0 −0.0541 −0.0330 −1.1186 Focal — 900.0 639.8 −317.5 486.8 −757.1 length f [mm]

The light source 8101 in this embodiment is also a Laser-Produced-Plasma source. The distance to the collector mirror 8103 is set to 100 mm. The collector mirror 8103 is a parabolic mirror generating a parallel ray bundle, wherein the light source 8101 is arranged in the focal point of the parabola. Therefore the field raster elements 8109 are concave mirrors to generate the secondary light sources at the corresponding pupil raster elements 8115. The focal length of the field raster elements 8109 is equal to the distance between the field raster elements 8109 and the corresponding pupil raster elements 8115. The distance between the vertex of the collector mirror 8103 and the center of the plate with the field raster elements 8109 is 1100 mm. The field raster elements 8109 are rectangular with a length X_(FRE)=46.0 mm and a width Y_(FRE)=2.8 mm. The arrangement of the field raster elements 8109 is shown in FIG. 73. The mean incident angle of the rays intersecting the field raster elements 8109 is 10.5°, the range of the incidence angles is from 8° up to 13°. Therefore the field raster elements 8109 are used at normal incidence.

The plate with the pupil raster elements 8115 is arranged in the focal plane of the field raster elements 8109. The pupil raster elements 8115 are concave mirrors. The arrangement of the pupil raster elements 8115 is similar to the arrangement shown in FIG. 74. The mean incidence angle of the rays intersecting the pupil raster elements 8115 is 10.0°, the range of the incidence angles is from 7° up to 13°. Therefore the pupil raster elements 8115 are used at normal incidence. Between the plate with the pupil raster elements 8115 and the field mirror 8125 the beam path is crossing the beam path between the collector mirror 8103 and the plate with the field raster elements 8109. The field mirror 8125 is a convex mirror. The distance between the center of the plate with the pupil raster elements 8115 and the center of the used area on the field mirror 8125 is 1550 mm. The mean incidence angle of the rays intersecting the field mirror 8125 is 13°, the range of the incidence angles is from 11° up to 15°. Therefore the field mirror 8125 is used at normal incidence.

The field mirror 8123 is a concave mirror. The distance between the center of the used area on the field mirror 8125 and the center of the used area on the field mirror 8123 is 600 mm. The mean incidence angle of the rays intersecting the field mirror 8123 is 7.5°, the range of the incidence angles is from 6° up to 9°. Therefore the field mirror 8123 is used at normal incidence.

The field mirror 8127 is a convex mirror. The distance between the center of the used area on the field mirror 8123 and the center of the used area on the field mirror 8127 is 600 mm. The mean incidence angle of the rays intersecting the field mirror 8127 is 78°, the range of the incidence angles is from 73° up to 82°. Therefore the field mirror 8127 is used at grazing incidence.

FIG. 82 shows another embodiment in a schematic view. Corresponding elements have the same reference numbers as those in FIG. 76 increased by 600. Therefore, the description to these elements is found in the description to FIG. 76. In this embodiment the field mirror 8225 and the field mirror 8223 are both concave mirrors forming an off-axis Gregorian telescope configuration. The field mirror 8225 images the secondary light sources 8207 in the plane between the field mirror 8225 and the field mirror 8223 forming tertiary light sources 8259. In FIG. 82 only the imaging of the central secondary light source 8207 is shown. At the plane with the tertiary light sources 8259 a masking unit 8261 is arranged to change the illumination mode of the exit pupil 8233. With stop blades it is possible to mask the tertiary light sources 8259 and therefore to change the illumination of the exit pupil 8233 of the illumination system. Possible stop blades has circular shapes or for example two or four circular openings. The field mirror 8223 and the field mirror 8227 image the tertiary light sources 8259 into the exit pupil 8233 of the illumination system forming quaternary light sources 8235.

FIG. 83 shows another embodiment in a schematic view. Corresponding elements have the same reference numbers as those in FIG. 82 increased by 100. Therefore, the description to these elements is found in the description to FIG. 82. In this embodiment the collector mirror 8303 is designed to generate an intermediate image 8363 of the light source 8301 in front of the plate with the field raster elements 8309. Nearby this intermediate image 8363 a transmission plate 8365 is arranged. The distance between the intermediate image 8363 and the transmission plate 8365 is so large that the plate 8365 will not be destroyed by the high intensity near the intermediate focus. The distance is limited by the maximum diameter of the transmission plate 8365, which is in the order of 200 mm. The maximum diameter is determined by the possibility to manufacture a plate being transparent at EUV. The transmission plate 8365 can also be used as a spectral purity filter to select the used wavelength range. Instead of the absorptive transmission plate 8365 also a reflective grating filter can be used. The plate with the field raster elements 8309 is illuminated with a diverging ray bundle. Since the tilt angles of the field raster elements 8309 are adjusted according to a collecting surface the diverging beam path can be transformed to a nearly parallel one. Additionally, the field raster elements 8309 are tilted to deflect the incoming ray bundles to the corresponding pupil raster elements 8315.

FIG. 84 shows an EUV projection exposure apparatus in a detailed view. The illumination system is the same as shown in detail in FIG. 77. Corresponding elements have the same reference numbers as those in FIG. 77 increased by 700. Therefore, the description to these elements is found in the description to FIG. 77. In the image plane 8429 of the illumination system the reticle 8467 is arranged. The reticle 8467 is positioned by a support system 8469. The projection objective 8471 having six mirrors images the reticle 8467 onto the wafer 8473, which is also positioned by a support system 8475. The mirrors of the projection objective 8471 are centered on a common straight optical axis 8447. The arc-shaped object field is arranged off-axis. The direction of the beam path between the reticle 8467 and the first mirror 8477 of the projection objective 8471 is convergent to the optical axis 8447 of the projection objective 8471. The angles of the chief rays 8445 with respect to the normal of the reticle 8467 are between 5° and 7°. As shown in FIG. 84, the illumination system 8479 is well separated from the projection objective 8471. The illumination and the projection beam path interfere only nearby the reticle 8467. The beam path of the illumination system is folded with reflection angles lower than 25° or higher than 75° in such a way that the components of the illumination system are arranged between the plane 8481 with the reticle 8467 and the plane 8483 with the wafer 8473.

In a scannertype lithography projection exposure apparatus equipped with a pulsed light source the dose at a specific point within the object to be illuminated depends on the number of light pulses hitting the reticle plane. Assuming a stable pulse frequency of the light source and a rectangular intensity profile this number fluctuates by one count. To obtain a high dose uniformity it is advantageous that the fluctuation of the dose due to the discrete pulse sequence is minimized. This can be achieved if the first pulse and the last pulse of a pulse sequence do not contribute to the dose of an object point as much as the pulses in the middle of a pulse sequence do. A trapezoid intensity profile as shown in FIG. 87B can provide for such a behavior. Also other intensity profiles except an perfect rectangular profile are possible, e.g. a Lorentz-profile or a Gaussian profile.

FIGS. 85 to 87 show the influence of superposition of the images of different first raster elements in the image plane on the intensity profile of the illumination in scanning direction, here in y-direction. To describe the effect the illumination system it is assumed to have no field mirrors for forming the arc-shaped field. Therefore images of the rectangular first raster elements are also rectangular in the image plane having the same aspect-ratio as the field raster elements. Such a rectangular field in the image plane is shown in FIG. 85 and denoted with reference number 8500. If the images 8600, 8602, 8604 of the first raster elements are superimposed almost congruently, as shown in FIG. 86A, an almost rectangular intensity profile 8606 as shown in FIG. 86B results in scanning direction.

In FIG. 87A a case is shown where the images of the first raster element are not superimposed congruently in the image plane. In this application non-ideal superposition means that the images of the first raster elements are not fully congruent in the field plane. This can be achieved in that the first raster elements of the first raster element plate have a different size, e.g. a different extension in y-direction, which coincides with the scanning direction in a scannertype lithography projection exposure apparatus.

To superimpose three different images 8700, 8702, 8704 not congruently in the image plane in a first embodiment the raster element plate comprises three different raster elements with a different extension in y-direction and therefore different aspect ratios. The intensity profile in y-direction resulting from the field in the image plane as shown in FIG. 87A is depicted in FIG. 87B. As it is apparent from FIG. 87B a nearly trapezoid intensity profile results from the field as shown in FIG. 87 A.

A non-congruent superposition of the images of the first raster elements in the image plane can also be achieved if all first raster elements have identical size, i.e. a identical aspect ratio but the corresponding second raster elements have different optical power. In such a case the images of the first raster elements have a different size in the image plane and thus are not superimposed congruently.

To achieve a non-congruent superposition of the images of the first raster elements in the image plane it is possible to combine the two aforementioned methods, i.e. first raster elements of different size and different optical power of the second raster elements.

A raster element plate with first raster elements as shown in FIG. 73 having raster elements of different size, i.e. extension in y-direction and therefore different aspect ratio is shown in FIG. 88. FIG. 88 shows a raster element plate with four first raster elements with a first extension in y-direction 8800.1, 8800.2, 8800.3 8800.4, four first raster elements with a second extension in y-direction 8802.1, 8802.2, 8802.3, 8802.4 and four first raster elements with a third extension in y-direction 8804.1, 8804.2, 8804.3, 8804.4. The raster elements are arranged symmetric on the raster element plate in respect to the x- and the y-axis.

For obtaining also a sufficient telecentricity during the scan process it is necessary to fill the exit pupil for each field point for the different first raster elements of different size with tertiary light sources in a uniform manner. This can be achieved if the deflection angles of the deflected ray bundle of the plurality of the first raster elements is chosen in such a manner that the corresponding plurality of second raster elements are nearly point symmetric to the center of the pupil raster element plate shown, for example, in FIG. 74. In this application nearly point symmetric means that the telecentricity error in the exit pupil for each field point is less than 1 mrad, preferably less than 0.1 mrad. Since the tertiary light sources in the exit pupil for each field point of the object field corresponds to the arrangement of the second raster elements on the pupil raster element plate, the exit pupil of each field point is also filled point symmetric with tertiary light sources as shown in FIG. 89. FIG. 89 shows schematically the principle of arrangement of first and second raster elements. Two first raster elements 8900.1 and 8900.2 of identical size, which are arranged symmetrically with respect to an axis of symmetry 8910 in the first raster element plate 8950. In this case the axis of symmetry is the x-axis, which is perpendicular to the scanning direction. The deflection angles of the first raster elements 8900.1 and 8900.2 are chosen such that the corresponding pupil facets 8980.1 and 8980.2 are arranged point symmetrically with respect to the center of the second raster element plate 8990.

As discussed in the examples before e.g. in FIGS. 73-79 the light source, which illuminates the first raster element plate is denoted as primary light source. The plurality of first raster elements forms a plurality of secondary light sources. The second raster element plate is arranged in or near the site of the secondary light sources.

The exit pupil for seven field points is shown in FIG. 90. Point 9000 lies outside the field in the image plane. Therefore no illumination occurs in the exit pupil 9050 for this point. Point 9002 lies within the filed. The images of the first raster elements 8804.1, 8804.2, 8804.3, 8804.4 of the filed raster element plate shown in FIG. 88 are superimposed in this field point. Therefore four tertiary light sources 9010.1, 9010.2, 9010.3, 9010.4 illuminate the exit pupil 9052. The four tertiary light sources 9010.1, 9010.2, 9010.3, 9010.4 are symmetric to the center C of the exit pupil.

In field point 9003 the images of eight first raster elements 8804.1, 8804.2, 8804.3, 8804.4, 8802.1, 8802.2, 8802.3, 8802.4 of the raster element plate shown in FIG. 88 are superimposed. In the exit pupil 9054 eight uniformly distributed tertiary light sources 9010.1, 9010.2, 9010.3, 9010.4, 9012.1, 9012.2, 9012.3, 9012.4 are depicted which are point symmetric to the center of the exit pupil.

In field point 9004 the images of all twelve first raster elements 8804.1, 8804.2, 8804.3, 8804.4, 8802.1, 8802.2, 8802.3, 8802.4, 8800.1, 8800.2, 8800.3, 8800.4 of the raster element plate in FIG. 88 are superimposed. In the exit pupil 9056 twelve uniformly distributed tertiary light sources 9010.1, 9010.2, 9010.3, 9010.4, 9012.1, 9012.2, 9012.3, 9012.4, 9014.1, 9014.2, 9014.3, 9014.4 are depicted which are point symmetric to the center of the exit pupil.

For field point 9005 the images of eight first raster elements are superimposed. The situation corresponds to the situation in filed point 9003. The exit pupil 9058 is illuminated by eight tertiary light sources.

For field point 9006 the images of four first raster elements are superimposed. The situation corresponds to the situation in filed point 9002. The exit pupil 9060 is illuminated by four tertiary light sources.

Point 9007 lies outside the field, therefore the exit pupil 9062 is not illuminated.

If one scans an object in y-direction at the beginning 4 tertiary light sources are turned on then 8 and at last 12 light sources are turned on. Then four light sources to a total of eight light sources are turned off, in the next step further four light sources to a total of four light sources are turned off and outside the field in the image plane the exit pupil is not illuminated.

As a result of the special assignment of first raster elements and second raster elements the center of gravity of the illumination of the exit pupil is located in the center of the exit pupil for each field point. Thus the telecentricity of the illumination system does not depend on the field position, a prerequisite for telecentric wafer exposure. The described feature of the exit pupil holds for any axially symmetric illumination of the first raster elements and is purely based on the assignment of first and second raster elements.

According to the invention an illumination system is provided which is insensitive to fluctuations of the pulse sequence of the primary light source. Moreover the illumination system according to the invention is characterized by a optimal telecentricity during all phases of the scan process. In contrast to that illumination systems of the state of the art consider only scanning integrated telecentricity. 

1. (canceled)
 2. An illumination system for illuminating a region of a surface with illumination light emitted from a light source, the system comprising: an incidence-side reflection-type fly-eye optical system comprising multiple first reflective elements arranged in rows; an emission-side reflection-type fly-eye optical system comprising multiple second reflective elements arranged in rows such that each second reflective element corresponds to and receives illumination light from a respective first reflective element of the incidence-side reflection-type fly-eye optical system; and a condensing optical system comprising two reflective mirrors that guide the illumination light, reflected by the emission-side reflection-type fly-eye optical system, to the region of the surface, wherein at least one of the reflective mirrors has a center of curvature that is optically eccentric with respect to a normal to the surface at the center of the illuminated region.
 3. The system of claim 2, wherein the two reflective mirrors are spherical mirrors.
 4. The system of claim 2, wherein the two reflective mirrors are aspherical mirrors.
 5. The system of claim 2, wherein the two reflecting mirrors are a spherical mirror and an aspherical mirror, respectively.
 6. The system of claim 2, wherein: each of the first reflective elements has a respective effective reflecting surface having a respective center and a respective inclination; each of the second reflective elements has a respective effective reflecting surface having a respective center and a respective inclination; and the inclinations of the second reflective elements are set such that rays of the illumination light, propagating from the respective centers of the respective effective reflecting surfaces of the first reflective elements and reflecting from the respective centers of the respective effective reflecting surfaces of the second reflective elements, are converged by the condensing optical system at a point in the region of the surface.
 7. An exposure apparatus for transferring a pattern from a mask onto a photosensitive substrate, the apparatus comprising an illumination system as recited in claim 2 situated and configured to illuminate the mask.
 8. A method for manufacturing microdevices, comprising: exposing a photosensitive substrate to a pattern defined on a reflective reticle, using an exposure apparatus as recited in claim 7; and developing the exposed photosensitive substrate.
 9. An exposure apparatus, comprising: an illumination system situated and configured to illuminate a region of a surface with illumination light emitted from a light source, the illumination system comprising (i) an incidence-side reflection-type fly-eye optical system comprising multiple first reflective elements arranged in rows, (ii) an emission-side reflection-type fly-eye optical system comprising multiple second reflective elements arranged in rows, wherein each second reflective element corresponds to and receives illumination light from a respective first reflective element of the incidence-side reflection-type fly-eye optical system, and (iii) a condensing optical system comprising two reflecting mirrors that guide the illumination light, reflected by the emission-side reflection-type fly-eye optical system, to the region of the surface; wherein (iv) the two reflecting mirrors have respective centers of curvature, and (v) the condensing optical system has an optical axis that passes through the centers of curvature of the two reflecting mirrors but is not parallel to a normal to the region of the surface at the center of the region.
 10. An exposure apparatus, comprising: an illumination system situated and configured to illuminate a region of a surface with illumination light emitted from a light source, the illumination system comprising (i) an incidence-side reflection-type fly-eye optical system comprising multiple first reflective elements arranged in rows, (ii) an emission-side reflection-type fly-eye optical system comprising multiple second reflective elements arranged in rows, wherein each second reflective element corresponds to and receives illumination light from a respective first reflective element of the incidence-side reflection-type fly-eye optical system, and (iii) a condensing optical system comprising two reflecting mirrors that guide the illumination light, reflected by the emission-side reflection-type fly-eye optical system, to the region of the surface; wherein (iv) the condensing optical system has an optical axis, the two reflecting mirrors have respective centers of curvature, (v) the emission-side reflection-type fly-eye optical system has an aperture plane, (vi) a perpendicular line passing through a center of the aperture plane is a virtual optical axis, and (vii) the optical axis of the condensing optical system passing through the centers of curvature of the two reflecting mirrors of the condensing optical system is not parallel to the virtual optical axis.
 11. An exposure apparatus, comprising an illumination system situated and configured to illuminate a region of a surface with illumination light emitted from a light source, the illumination system comprising (i) an incidence-side reflection-type fly-eye optical system comprising multiple first reflective elements arranged in rows, (ii) an emission-side reflection-type fly-eye optical system comprising multiple second reflective elements arranged in rows, wherein each second reflective element corresponds to and receives illumination light from a respective first reflective element of the incidence-side reflection-type fly-eye optical system, and (iii) a condensing optical system that guides the illumination light, reflected by the emission-side reflection-type fly-eye optical system, to the region of the surface, the condensing optical system comprising an incidence-side convex mirror and an emission-side concave mirror.
 12. The exposure apparatus of claim 11, wherein: the emission-side reflection-type fly-eye optical system has a periphery; the first reflective elements of the emission-side reflection-type fly-eye optical system have respective inclination angles; the closer to the periphery, the greater the inclination angles; and the entire emission-side reflection-type fly-eye optical system has a convergent action.
 13. The exposure apparatus of claim 11, wherein: the convex mirror and concave mirror have respective centers of curvature; and at least one of the centers of curvature is optically eccentric with respect to a normal to the region of the surface at the center of the region.
 14. The exposure apparatus of claim 12, wherein: the convex mirror and concave mirror have respective centers of curvature; the emission-side reflection-side fly-eye optical system has an aperture plane; a perpendicular line passing through a center of the aperture plane is a virtual optical axis; and at least one of the centers of curvature is eccentric with respect to the virtual optical axis.
 15. The exposure apparatus of claim 12, wherein: the condensing optical system has an optical axis; the convex mirror and concave mirror have respective centers of curvature; and the optical axis, passing through the respective centers of curvature of the convex mirror and the concave mirror, is not parallel to a normal to the region of the surface at the center of the region.
 16. The exposure apparatus of claim 12, wherein: the condensing optical system has an optical axis; the convex mirror and concave mirror have respective centers of curvature; the emission-side reflection-side fly-eye optical system has an aperture plane; a perpendicular line passing through a center of the aperture plane is a virtual optical axis; and the optical axis, passing through the respective centers of curvature of the convex mirror and the concave mirror, is not parallel to the virtual optical axis. 